Method of forming a coating on a surface of a substrate

ABSTRACT

A reinforcing underlayment including dry uniform particles evenly applied to a wet bonding material layer on a surface of a substrate. The substrate, including the layers, is then cured to harden the one or more of the layers. A final coating or topcoat is applied to the cured surface of the substrate. The dry particles are evenly distributed onto the bonding material layer creating a uniform surface for subsequent coatings. The dry particles increase the strength of the liquid coatings increasing solid particle density within the coating system and thereby imparting properties not available for the liquid coatings. The present invention enables a user to easily introduce very heavy, dense, strong particles into a liquid coating and allows the user to apply very dense, heavy particles into and onto a wet bonding material layer followed by a subsequent wet topcoat layer which is cured as one contiguous material with reinforcement and underlayment strengthening coming from the added, dry particles.

PRIORITY CLAIM

This application is a continuation of, claims priority to and the benefit of U.S. patent application Ser. No. 12/904,351, filed on Oct. 14, 2010, which is a continuation of, claims priority to and the benefit of U.S. patent application Ser. No. 12/612,240, filed on Nov. 4, 2009, now U.S. Pat. No. 7,838,082, which is a continuation of, claims priority to and the benefit of U.S. patent application Ser. No. 11/844,708, filed on Aug. 24, 2007, now U.S. Pat. No. 7,618,684, which is a continuation of, claims priority to and the benefit of U.S. patent application Ser. No. 11/157,001, filed on Jun. 20, 2005, now U.S. Pat. No. 7,261,925, which is a continuation of, claims priority to and the benefit of U.S. patent application Ser. No. 10/318,503, filed on Dec. 12, 2002, the entire contents of which are each incorporated by reference herein.

BACKGROUND

Coatings on parts and products are used in industry for several different purposes. Certain coatings, for instance, are applied to surfaces to provide low friction, non-stick, abrasion resistant or other specific properties. When a harder object contacts a surface and friction is created, the friction of the force on the surface wears away a portion of that surface. Over time, the cumulative effect of repetitive or continuous contact between the object and the surface causes a substantial portion of the surface to wear away so that the surface is no longer functional. One example of such an object applying such a force is the force applied between metal cooking utensils (i.e., the objects) and cooking surfaces such as the non-stick coatings applied to surfaces of pots or pans. Continuous contact between the utensils and these cooking surfaces causes the coatings applied to the surfaces, such as non-stick coatings, to gradually wear away and diminish the effectiveness of the coatings. Therefore, manufacturers have developed abrasion-resistant, non-stick coatings incorporating harder and more durable particles, which resist the abrasive forces created by cooking utensils as the utensils contact the coated surface of the cooking surfaces. As a result, these coatings enhance the durability of cooking surfaces, however, the coatings compromise the non-stick properties of the surface. In addition, the introduced hard particles are not attached firmly to the surface to provide rigid support of the relatively soft non-stick material topcoat. The loose particles can therefore, dislodge from the surface relatively easily.

Wear also occurs, for example, when a surface or surfaces of a component are subject to continuous and prolonged forces such as rotational or reciprocating forces applied by a first object which basically, rubs against the surface of a second object, creating friction between the objects. The friction generally wears away one or both of the surfaces. If one surface is sacrificial in nature, commonly including softer particles or materials versus harder particles or materials, it will wear sooner than the surface including the harder, more durable surface. To prevent this, coatings, which are comprised of relatively soft materials, are applied to a part or parts so that the parts can be replaced easily when the coating wears out. An example is a PTFE-coated solenoid plunger inside a housing of a solenoid which must remain dry or without fluid lubrication in use. In operation, the PTFE-coated solenoid plunger wears at a predictable rate due to friction created between the surface of the plunger and the surface of the housing. Therefore, the plunger can be exchanged for a newly coated plunger on a predictable maintenance schedule. This is particularly appropriate when no fluid lubricants can be introduced into a system.

Another example of intended sacrificial wear is a wear end plate in a rotary gear pump. A thin layer of bronze is attached to, for example, a replaceable iron plate. This plate can be changed when the bronze layer wears.

Other methods of applying reinforcing coatings to surfaces to provide wear resistance for soft coatings have been developed. In another example, metal spray coatings, such as bronze, are arc sprayed or flame sprayed onto metal parts to produce an intermittent bronze coating, which is subsequently coated with PTFE and finished into a smooth surface. The wear resistance of the bronze particles reinforce the relatively weak strength of the PTFE, which has a very low friction however with low wear resistance. This bronze/PTFE coating system will wear longer than a unreinforced PTFE coating.

Coatings are also used for many applications such as for rust resistance, corrosion resistance and as functional or protective coatings. In one example, plastic electric motor brush covers are coated with coatings containing metal to absorb and conduct electrical emissions to reduce electrical emissions coming from electric fuel pumps in an automobile or other vehicle.

Coatings may be applied in various different known manners. One method of applying the coatings is to spray the coatings on to a substrate such as metallic material. The coatings are usually sprayed so that the coatings completely cover the surface or surfaces of the substrate that require the coating. Typically, a bonding agent such as primer is used to initially coat the substrate to promote the adhesion of the coating to the substrate. The bonding agent or primer is typically applied to a cleaned surface of the substrate. Additionally it has been known to add particles to the liquid primer and/or the base coating to increase the abrasion resistance of the liquid coating and primer. As a result, the coating or coatings applied to the substrate has greater abrasion resistance.

In one known coating process described in U.S. Pat. No. 5,492,769, hard particles are embedded in a surface layer on a substrate to improve the scratch or surface wear resistance of the substrate. The surface of the substrate is prepared and then a thin layer of discrete, hard particles are applied to the surface of the substrate. The surface of the substrate is then softened using heat or a solvent. The surface may also be softened prior to the application of the particles to the surface if needed. After the surface of the substrate is softened, the particles are embedded into the softened surface of the substrate using pressure. The particles are embedded in the surface so that approximately 50% of the volume of the particles are located at the surface layer. The softened surface is then allowed to re-harden, which embeds and bonds the particles to the surface of the substrate. This bonding method is generally limited to substrates such as plastics, polymers and softer metals, which are relatively softer than the particles being embedded in the surfaces of these substrates.

In another known coating process, solid particles are mixed with a liquid primer prior to applying the primer to the surface of the substrate. The particles are non-uniform or irregular in shape and the particles are also non-uniformly dispersed or mixed within the primer because the distribution of the particles cannot be controlled. Therefore, as the primer mixture is applied to the surface of the substrate, the unevenly distributed particles within the primer tend to pool or bunch up on particular areas of the substrate, particularly if the particles are very heavy. In addition, heavy introduced particles in a liquid coating system, will settle in different densities on horizontal, vertical or other pockets or depressions of a coated part. As a result, certain portions of the substrate include more particles than other portions of the substrate. This creates an uneven or non-uniform distribution of introduced particles on the substrate that has been coated. Thus, when a topcoat or final coat that contains heavy or dense particles is applied to the substrate, the topcoat or final coat also pools or builds up in the same areas on the substrate as the particles in the primer mixture. This diminishes the finish strength or quality of the surface of the finished product.

In a further known coating process, the particles are flame sprayed or applied in a molten droplet form and propelled onto the surface of the substrate. The molten particles adhere to the surface of the substrate. However, the molten particles are typically applied or sprayed onto the substrate at such a rate that the molten particles flatten or partially flatten as the particles hit or contact the surface of the substrate. Thus, the surface of such substrates are often uneven because of the varying shapes of the applied molten particles. As described above, this causes an uneven surface area or non-uniform surface area so that the coating that is subsequently applied to the particles is also uneven and non-uniform.

One known wear resistant coating sold under the trademark Excalibur® by Whitford Worldwide is formed using molten stainless steel particles and provides non-stick and initial low friction characteristics to surfaces of substrates but is limited in its application exclusively to metal substrates. This coating is applied to a substrate surface by first grit blasting the surface with a suitable abrasive to roughen it and promote the adherence of subsequent material layers. Then, stainless alloy particles are electric-arc sprayed onto the roughened metal surface of the substrate. The particles cool and harden forming varying surface configurations including high peaks and low peaks, which do not completely bond to the surface. Next, several layers of fluropolymer coatings are applied to the particle layer and permanently bond all of the coatings in place on the surface of the substrate. The application of the molten particles, however, incurs the same problems as described above. Thus, the distribution of the size and shape of the molten particles in this process are generally not uniform or evenly distributed on the surface of the substrate.

The varying particle shapes in the above processes and coatings affect the uniform distribution of the particles on the surface of the substrate. The particles are applied to the surface of the substrate to increase the abrasion resistance of the subsequently applied coating. The irregularly shaped particles generally are not evenly or uniformly distributed on the surface of the substrate because the irregular surfaces of the particles generally do not correspond with each other. In addition, particle size may vary where some particles are much larger than other particles. Thus, some particles bunch together while other particles are spread apart based on the size and shape of the particles. This causes the particles to be non-uniformly distributed and be of non-uniform size on the surface of the substrate, which in turn, causes the coating applied to the particles to be non-uniform.

Furthermore, the irregular shape of the particles limits the consistency of the surface area created by the addition of the non-uniform particles to the substrate. As described above, irregularly shaped particles may bunch up or be spread apart on a percentage of the surface of the substrate and consist of varying heights. Therefore, the maximum surface area of each particle may not be exposed to prevent coating wear depending on whether the particles are partially or wholly covered by other particles and whether particles, such as molten metal particles, are deposited on top of previously deposited particles. Because the maximum exposable surface area of each particle is not consistently available, the total surface area generated by the addition of the particles to the substrate is limited or diminished. As a result, the bond between the coating and the particles is less consistent and weaker than if the maximum exposable surface area is exposed for coating by subsequent topcoats. This results in loose or non-adherent particles on top of the previously deposited particles.

Another reinforced metal/PTFE coating system consists of an electric arc spray of stainless steel or titanium particles subsequently coated with a two coat PTFE commercial non-stick coating. In one example, an aluminum cooking pan is grit blasted with aluminum oxide to roughen the aluminum surface to assist the mechanical attachment of the dissimilar metal stainless steel or titanium particles to the pan. The stainless steel particles are heated to provide molten stainless steel particles which are propelled toward the grit blasted surface. The deposited molten stainless steel or titanium particles cool and the result is a rough, varied group of various shaped metal particles which are mechanically attached to the rough grit blasted aluminum surface. This irregular surface, which resembles a mountain range of irregular shaped stainless steel particles, is then coated with two or more coatings of a commercial non-stick coating. When cooking utensils contact the reinforced non-stick coating, wear is reduced as the metal particles take the mechanical abrasion created by cooking utensils.

This stainless steel/PTFE coating system is exemplified by the Whitford Corporation's Excalibur® coating system. After the stainless particles are deposited on the aluminum, the Excalibur® coating system includes the steps of removing non-adherent particles of loose stainless steel from the aluminum. The loose, non-adherent or slightly adherent particles of stainless steel are removed by wire brushing, air cleaning or both prior to the application of the topcoats of PTFE based non-stick coatings.

Uneven or non-uniform distribution of a coating on a surface of a substrate causes several different problems or issues for manufacturers. An uneven coating on the surface of a particular part will cause uneven wear of the parts and subject the part to more friction if particles protrude through the final coating or topcoat. Conversely, if there are less reinforcing particles in an applied coating due to the non-uniform distribution of the reinforcing particles in the coating on the surface of the part, the coated surface of the part will have less wear resistance or wear protection. Thus, the greater friction and wear on the part may cause the part to fail during operation or not last as long in operation. Additionally, an uneven coating quality may cause a part to not perform as well in operation. An uneven surface roughness due to uneven internally distributed and dispersed reinforcing particles may also cause a part or parts requiring specific tolerance levels or dimensions to be outside acceptable limits and therefore not meet desired designed specifications, fail during assembly or during operation. If the coating over the irregular stainless particles is designed to provide non-stick or release properties, taller or larger stacked particles protruding through the coating quickly wear, dislodge easily and diminish the desired non-stick or release properties and cause sticking instead of preventing it.

In a mechanical wear situation, if the dispersed lubricant/reinforcing materials within the liquid coating, whether the materials are metal or non-metallic materials, are protruding, mechanical interference may be caused thereby preventing component motion. If the particles are not dispersed uniformly, the wear resistance and consistency of performance is diminished.

Additionally, liquid coating end use requirements for reinforcing a coating on a surface of a substrate to provide augmentation of, for instance, a soft coating to increase the wear resistance is presently accomplished by introducing hard particles to the liquid coating. The desired laminar placement of specific particles in the coating is impossible when particles are dispersed in a liquid coating. The placement of reinforcing particles within a coating in a specific area is not possible with a liquid coating containing dispersed particles. Furthermore, the placement of different wear resistant particles in a specific order or location with different properties cannot be done in a liquid coating application. Also, providing an extremely dense, near 100% dense layer of reinforcing particles under a smooth topcoat is not possible with a liquid coating. Even if multiple layers are applied, the possibility of particles moving and migrating in a liquid coating prevent assurance of and determination of density before subsequent coating layers are applied as the liquid carrier reduces the density of the interconnected particles. Additionally, if a liquid coating application includes heavy, hard particles such as certain abrasive particles, the coating is difficult to apply using conventional pumps and spray guns, which causes the pumps and spray guns to wear more rapidly.

Accordingly, there is a need for a coating method, and specifically a coating reinforcing underlayment and method of manufacturing same which enables a reinforced coating system to be evenly, uniformly and densely applied to the surface of a substrate.

SUMMARY

The present invention relates in general to coated substrates, and specifically to a coating reinforcing underlayment for coating substrates on which a topcoat such as PTFE, will be applied and a method of manufacturing the coating reinforcing underlayment.

One embodiment of the coating reinforcing underlayment of the present invention is applied to a substrate, which may be any suitable substrate, and which includes a layer of a wet bonding material applied to the surface of the substrate to be coated and a single layer of substantially uniform dry particles applied directly into and to the wet bonding material layer. In another embodiment, the above process is repeated until a desired thickness is achieved or until a specific number of layers are applied to the surface of the substrate.

In one presently preferred embodiment of the method of the present invention, a substrate is positioned on a support so that a surface or surfaces of the substrate may be coated. Initially, the surface of the substrate is cleaned with a cleaner to remove impurities which may be present on the surface of the substrate. The cleaner such as a solvent may be manually applied or mechanically applied to the substrate. In one embodiment, grit blasting or sandblasting is used to clean the surface of the substrate. Alternatively, the substrate may be pre-cleaned or the method may be performed in a “clean room” where the cleaned part is manufactured and the step is not necessary.

Once the surface of the substrate is cleaned, a layer of a wet bonding material such as a primer is applied to the surface of the substrate. The wet bonding material may include one or more additives which change or enhance one or more characteristics of the wet bonding material. For example, in one embodiment, the wet bonding material includes an ultraviolet light cure resin. In another embodiment, the wet bonding material includes an electron beam cure resin. It should also be appreciated that the bonding material may be any suitable bonding material or agent. The bonding material layer is formulated to also improve the bonding capabilities of the subsequent coating layer or layers applied to the surface of the substrate in addition to retaining the particles. The layer of wet bonding material is preferably applied uniformly so as to avoid forming a thick layer, which is thicker than what is necessary or required, and avoid drippings which may detract from the bonding ability to the substrate.

In one embodiment, while the bonding material layer is still wet, a single layer of substantially uniform dry particles such as a powdered engineering plastic, dry metal particles, dry ceramic particles or pre-coated or micronized dry particles are sprayed over the wet bonding material. The powdered or dried particles adhere to the wet surface area of the bonding material in an even manner. In this embodiment, when the wet bonding material is completely coated with one layer of the uniform powdered particles, additional dry particles cannot stick to the bonding material layer because the adhered particles attached to the bonding material layer act as a barrier to other particles attaching to the wet bonding material layer. Therefore, the dry particles do not build up or form an uneven surface area on the surface of the substrate. Additionally, the wet bonding material layer may be a thick layer where the uniform particles sink into and are completely covered by the wet bonding material layer. In another embodiment, the wet bonding material layer is a substantially thin layer on the surface of the substrate and a substantial portion of the particles are exposed on the wet bonding material layer. Once applied, the dry particles substantially increase the surface area of the substrate.

The substantially uniform dry particles are preferably consistent or include particles that have substantially consistent granular size and shape. In one embodiment, the particles are substantially round in shape. It should be appreciated that any suitable size or shaped particles may be employed in the present method such as flat-shaped, flake-shaped, cylindrical-shaped, oblong-shaped or leaf-shaped particles to suit the end use of the part being coated with this process. In one embodiment, the dry particle sizes and shapes are determined based on the end use and desired specifications and chemical composition of the coated substrate.

In one example, angular particles such as triangular shaped particles or similar particles are used to create a rough surface on a substrate by applying the angular particles to the bonding material layer on the surface of the substrate. In another example, less abrasive and lower friction surfaces are created by using shaped particles such as spherical or round shaped particles. In a further example, one or more combinations of different shaped uniform particles are used on a surface of a substrate. Thus, uniformly sized or shaped groups of uniform particles or different sized or shaped particles may be applied to a surface of a substrate. The wet bonding material layer and the substantially uniform dry particle layer are applied to the surface of the substrate until a desired thickness is achieved. Any suitable thickness ranges may be used as desired and determined by the manufacturer. Additionally, the density of the particles may vary depending on the design specifications of an end product or final product. The density or distribution of the particles may vary from covering or adhering to approximately ten percent of the surface of the substrate to approximately one hundred percent of the surface. Similarly, the density of the uniform particles may vary depending on the end use criteria.

In another embodiment, low friction uniform particles are applied to a lower layer followed by another very thin outer or upper layer of very fine abrasive particles. This system initially micro-abrades and smoothes out a counterface or counter surface of relatively rough metal which the coating wears against until the abrasive layer is worn down. After the thin abrasive layer is worn, the underlying layer of non abrasive friction reducing particles provides low friction to the now smooth counterface or opposing surface. This embodiment may for instance be used in shock absorbers where a low quality relatively rough metal internal surface of tubing is wearing against a coated piston.

The types of coatings and/or uniform particles applied to a substrate may be any suitable type of particle as generally as indicate above. In one embodiment, whisker or rod shaped particles such as carbon fibers or carbon whiskers or nickel whiskers are applied to a surface of a substrate to reduce wear on the surface and provide a non-metallic or metallic conductive surface for industries where electrically conductivity is an issue or a requirement. In another embodiment, aramid fibers or engineered plastic particles or fibers are applied to a substrate to strengthen the surface of the substrate. The aramid fibers include Kevlar® or Nomex® fibers which are introduced in substantially the same manner as the carbon fibers or whiskers. The Kevlar® or Nomex® fibers or materials can be either a pulp, which includes loose, fluffy fibers which is further ground into fibrillated fine powder, or can be other suitable forms such as round particles or semi-round dry particles. The aramid particles provide non-metallic wear resistance and have good bonding ability with both the basecoat and subsequent topcoats. Thus, the applied aramid fibers or materials create a dense layer of aramid or Kevlar® particles on the surface of the substrate, which is then coated with a topcoat or other suitable final coating. However, if a very high temperature, moderate friction (i.e., low abrasion) surface is desired, a topcoat or final coating is not applied to the layer of aramid fibers. In another embodiment, diamond particles are applied to the wet bonding material layer. Although this option has a much greater cost than other particles, the diamond particles provide greater wear resistance and less friction on the surface. These particles add tribological benefits beyond those benefits of aramid fibers.

In another embodiment, specially treated, uniform plastic particles are applied to a surface of a substrate. The plastic particles can be pre-treated PTFE, ultra high molecular weight polyethylene (UHMW) and/or PE or another suitable material are applied to the wet bonding material on the surface of the substrate. The particles are irradiated or processed with an electron beam which causes changes to the surface of the particles, allowing them to wet more easily and to sink into the wet bonding material layer, instead of remaining on the top of the material bonding layer. Therefore, the plastic particles are strongly bonded to the layer and not easily dislodged from the surface. This process thereby enables the plastic particle layer to last longer.

In another alternate embodiment, anti-microbial particles such as silver or silver compounds are applied to the surface of a substrate to reduce and kill bacteria and other potential germs that may be located on a surface of a substrate such as a kitchen counter or a food storage vessel, container or a conveyor or hook in a meat packing facility. In this embodiment, a dense layer of anti-microbial material in a powder or particulate form is applied to the wet bonding material layer. In one aspect of this embodiment, the anti-microbial particle layer is the final layer. In another aspect, a thin topcoat or final coating is applied to the anti-microbial particle layer to provide a release or non-stick surface on the substrate. The above process can be repeated as necessary to maintain the effectiveness of the anti-microbial surface. In this aspect, the thin topcoat or topcoats do not completely cover the protruding anti-microbial particles.

In another embodiment, dry or powdered, ultra porous bronze particles are applied to the wet bonding material layer on the surface of a substrate. The ultra porous bronze particles include many openings and voids so that the particles are approximately seventy percent solid compared to over ninety percent solid for most porous bronze materials. The particles enable a user to infuse the very porous bronze particles with the wet bonding material after the bronze particles are deposited on the wet bonding material on a surface of a substrate. This method is used to add lubrication and “lock” or strongly secure the particles into the liquid bonding material layer to increase the bonding strength of the layers to hold the bronze particles to both the upper and lower coating layers on the surface of the substrate even after being exposed to abrasive forces. The particles may be any suitable porous metal particles such as stainless steel particles, nickel particles, bronze particles, iron particles, titanium particles or other suitable particles including a metal and/or metal alloys.

In another embodiment, porous metal particles such as the bronze particles described above are impregnated or infused with a material such as PTFE, which lowers the friction of the particles. In one aspect of this embodiment, bronze particles or any other suitable metal particles including approximately seventy percent voids (i.e., air) are vacuum impregnated with a suitable lower friction material such as PTFE. In another aspect of this embodiment, the bronze particles are soaked with the PTFE and then dried. The latter process leaves partial voids in the bronze particles. However, the particles are partially infused with PTFE, which adds low friction capabilities to the bronze.

In a further embodiment, catalyzed resins consisting of two parts or plural components such as epoxies or urethanes are used to coat a surface of a substrate. In one example, these catalyzed bonding agents are used to coat a substrate such as a plastic or low temperature metal to enhance the wear resistance of the surface of the plastic or metal while not affecting the strength of the plastic or metal.

In another embodiment, acid or chemical resistance is increased by applying non-metallic, non-plastic particles such as substantially uniform dry ceramic or mica flakes and/or mica particles to the wet bonding material layer. Other suitable particles may be used such as glass, ceramics, modified mica, boron nitride, silicon nitride and aluminum oxide particles. The dry ceramic or mica flakes and/or particles create a barrier or a substantial barrier to an acid or other chemical. The barrier created by the particles or flakes diverts the acid or chemical from directly attacking a base material such as a metal, by decreasing the inherent permeability and porosity of a base coating or coatings on the surface of a substrate. A torturous, indirect path or maze-like path chemicals must take to reach the underlying surface is created by the plates or flakes so that the chemical or acid is forced to take an indirect path around the mica particles or flakes thereby slowing and/or retarding the speed and dynamics of the chemical or acid that is trying to permeate the coating.

Once the plural component resin followed by dry particles are applied to the surface of the substrate, the bonding material and substantially uniform dry particle layer are cured by catalytic cure, by heating the layers, air-drying the layers or according to any suitable curing method. The curing process cures the resin or dry particles so that a strong bond develops between the substantially uniform dry particle layer and the wet bonding material layer as it hardens and also bonds to the base surface. Because the dry uniform particles were applied to the wet bonding material, the particles are tightly packed and form a single uniform, substantially even surface on the substrate. As a result, the substantially uniform dry particles increase the surface area on the substrate and enable a topcoat to be applied uniformly and evenly on the substrate. Additionally, the topcoat develops a strong bond with the dry particles below which is bonded to the substrate. This process may be repeated one or more times to increase the total thickness and chemical resistance of the coatings on the surface of the substrate.

In another embodiment, a wet bonding material layer including relatively small particles of a suitable low friction or soft material is first applied to the surface of a substrate. Next, a layer of uniform hard dry particles or other suitable hard particles is applied to the wet bonding material layer. Another layer of the initial wet bonding material mixture including the relatively smaller particles is then applied to the dry particle layer. The layers are dried using a suitable drying or curing process, which causes the top layer or second wet bonding material layer including the small soft particles to shrink and distribute the small soft particles amongst the hard particles. This creates an abrasion resistant and low friction surface.

The spraying or application of the dry particles to the wet bonding material layer on the surface of the substrate may be adjusted to enhance the strength of the bond between the bonding material and the dry particles and the density of the layers on the substrate. In one embodiment, the pressure of the dry particle spray and the rate of the spray is increased to increase the density of the particles in the material bonding layer. The greater the density of the particles and depth of the layers, the greater the strength and desired characteristics of the resultant coated substrate.

In another embodiment, an electrostatic, tribo-charged or opposite electrostatic charged powder spray method is used to apply the dry particles to the wet bonding material. The charged particle powder spray enables an operator to better control the application uniformity of the dry particles and thereby enhance the density and application of the dry particles to the wet bonding material on the substrate. In a further embodiment, the electrostatic powder spray is used to apply a topcoat over the dry particles such as a powder paint coating or fluoronated plastic powder coating to the surface of the substrate. In this embodiment, a bonding material and then a conductive material or thin conductivity enhancing coating is applied to the surface of the substrate. The powder topcoat or final coating is then cured in a convection or infrared oven, which heats and shrinks the powder coating onto the top of the dry particles.

In another embodiment, an applicator such as a sifter is used to uniformly apply the uniform particles to the wet bonding material layer. The sifter is similar to a conventional flour sifter and is used in certain applications depending on the size of the uniform particles.

In a further embodiment, ferromagnetic or magnetic dry particles are applied to a surface of a substrate to completely coat a surface of a substrate or form a shape, symbol, character or other suitable image on a surface of a substrate. Initially, a non-magnetic metal surface or glass surface or aluminum surface is coated with a wet bonding material. Magnetic particles such as special magnetic stainless steel, magnetic ferrite or ferrous particles are applied to the wet bonding material. These magnetic particles are attracted to the magnetic shape or symbol lying directly under the wet coated glass, aluminum or non-magnetic substrate, thereby creating a design in the finished coating.

In another embodiment, a surface or a portion of a surface of a substrate such as the surface of a part is masked or selectively coated with a suitable masking device or material so that the dry uniform particles can only be applied to the unmasked areas on the surface of the substrate. In this embodiment, the wet bonding material is generally applied to the entire surface or surfaces of the substrate and then a masking material or device is applied to a specific area or areas on the surface of the substrate. However, the wet bonding material layer can be applied to a pre-masked substrate to coat the selective areas of the substrate. Therefore, the dry uniform particles, which are subsequently applied to the surface of the substrate, adhere to the exposed portions of the wet bonding material layer but not the masked portions of the surface of the substrate.

The coating layer applied to the underlayment or wet layer and the dry second layer may be any suitable coating such as a topcoat layer. It should be appreciated that the method of manufacturing or forming the coating underlayment may be performed as described above by applying or spraying the coatings onto the surface of the substrate. Alternatively, the coatings and dry particles may be applied using other suitable coating and application methods. In one embodiment, the wet bonding material layer is applied by dipping the substrate either completely or partially in the wet bonding material layer.

Several different types of additives may be added to the topcoat or final coating to improve the performance characteristics of the coated substrate. In one embodiment, a counter face smoothening additive including relatively hard particles, is added to a topcoat or final coat, in either a liquid or dry powder form, to enable the coated substrate to smoothen or polish a rough surface or surfaces, which contact the surface of the coated substrate. It should be appreciated that any suitable additive may be added to the topcoat or final coating to improve the performance or desired characteristics of the coated substrate.

In another embodiment, the substrate previously coated with a wet bonding material layer and dry particle layer, may be electrostatically charged to attract the uniform dry particles having an opposite charge. In this embodiment, substantially uniform dry powder particles are electrostatically attracted to the substrate because the particles have an opposite charge to the surface of the substrate. In one example, a powder paint coating such as an epoxy or polyester is applied to a surface of a substrate. In this example, a liquid layer is applied to a surface of a substrate and then an electrically conductive dry particle material layer is applied to the surface. The powder coating is then applied and is electrostatically attracted to the conductive material outer layer. Because the powder coating does not include solvent, the coatings are cured in a convection or infrared oven even though the lower layer of the basecoat contains specific solvents. The solvents in the basecoat migrate through the dry powder before the top powder coat starts to jell and cure into a continuous coating. The powder coating heats up and shrinks over the top of the dry particle layer forming a uniform, evenly distributed topcoat layer on the surface of the dry particle layer.

Alternatively, non-electrical, tribo-charged dry paint topcoat particles can be applied to a grounded part. In this embodiment, a very thin wet layer remains wet while the powder coat is applied either electrostatically or via a tribo-charge (i.e., friction charge). The entire coated part is oven cured to simultaneously cure the wet and dry powder topcoats.

In another embodiment, the substantially uniform aluminum oxide particles are applied to a wet bonding layer surface of a substrate to achieve a desired roughness on the surface. The desired surface roughness is achieved by changing the size of the aluminum oxide particles applied to the surface. The application of the aluminum oxide particles to roughen a surface substantially minimizes the distortion to the surface, which occurs with conventional blasting methods, and enables a user to control the roughness of the surface. In addition, harder particles such as boron nitride particles or other suitable particles can be applied to the surface of the substrate to increase the penetration resistance of the surface.

In a further alternative embodiment, the dry uniform particles are pre-coated or encapsulated or micro-encapsulated or micronized with a bonding enhancing material prior to applying the dry particles to the wet bonding material layer on the surface of the substrate. The pre-treated particles further enhance the bonding strength of coated particles to the layers on the substrate and to subsequent topcoat layers. The wet bonding material used to pre-coat the dry particles may be the same or different than the bonding material layer applied to the substrate.

In one embodiment, the present method described above is used as a coating to attenuate or reduce magnetic, electromagnetic, radio or similar waves generated by electric machines or other devices. Electromagnetic absorbent particles such as metal particles are used to coat a surface or surfaces. The particles completely coat the surfaces and enhance the electromagnetic, microwave or other wave absorbing capabilities of the surfaces.

In one embodiment, the present invention may be employed to protect machine operators from potentially dangerous conditions. Certain machines such as a Magnetic Resonance Imaging (“MRI”) machines produce potentially harmful conditions. Generally, a MRI machine uses a nuclear magnetic resonance spectrometer to produce electronic images of specific atoms and molecular structures in solids, especially human cells, tissues, and organs. Exposure to the magnetic frequencies and radiation generated by a MRI machine over time may pose health risks to an operator. Similarly, it is desirable to block exterior magnetic fields from such equipment. Operators are protected and such equipment is usually protected from exterior magnetic fields by RF enclosures or magnetically shielded enclosures. Such enclosures include walls of layers of magnetic shielding material such as copper. Such materials including the fabrication and installation of such materials is relatively expensive. In accordance with the present invention, dense adsorptive coatings can be applied to the interior and/or exterior surfaces of the walls of such enclosures and made of less expensive materials. The dry particles can be round or flat flakes or combinations of, for instance, dry copper round and flat particles, assuring complete electrical conductivity. The dry coating or wet coatings can incorporate substances such as metals, which shield and absorb the magnetic frequencies and radiation. If the coatings are applied in a high vibration area, elastomeric urethanes and other suitable flexible bonding materials may be used to prevent cracking or separations on the coated substrate.

In another embodiment, a liquid bonding material layer such as an epoxy, which is thermally cured, is applied to the surface of the substrate. Metal particles are then introduced or applied using a dry powder spray mechanism. In one aspect of this embodiment, the metal particles are passed through a heating chamber or flame device, such as on a metal spray gun. The metal particles pass through an oxyacetylene flame raising the temperature of the particles as the particles are propelled towards the pre-applied wet bonding layer. Introduction of heat into the particles allows the wet bonding material layer to start curing or semi-curing. The curing or semi-curing occurs because the heat introduced into the coating starts to harden the bonding material layer after the particles have been immersed in the material layer due to the velocity and force of the particles propelled at the wet bonding material layer. In a further embodiment, several different metals are applied to the bonding material. In another embodiment, metals and non-metals are combined and applied to the bonding material layer to form the underlayment. Additionally, particles formed from a material from the imide family and particles formed from another family such as high-end imides can be used to form the reinforcing underlayment.

In an alternative embodiment, a coating system includes a plurality of coating applicators, at least one container having a wet bonding material, at least one container having substantially dry particles, wherein the containers are connected to the coating applicators. The containers are connected to the coating applicators with at least one coating line or tube, which transports the materials from the containers to the coating applicators. It should be appreciated that the coating applicators may be spray guns, electrostatic spray guns, powder spray guns or any other suitable applicators. The coating applicators are positioned adjacent to the surface or surfaces being coated on the substrate. Additionally, the coating applicators may apply the coatings at the same rate or at different rates.

In one example, multiple coating applicators such as two electrostatic spray guns or powder spray guns, apply an epoxy-based material to a surface of a substrate. The epoxy is made up of relatively dry particles which are applied using electrostatic attraction to the surface. While the epoxy is in place, a thin layer of a wet bonding material is fog-sprayed or applied to the epoxy particles to slightly dampen the surface of the particles. Then, a powder spray of aluminum oxide, bronze, ceramic, glass or any other suitable material is applied to the bonding material on the particles. The layers are then heated or cured at one time. Subsequently, a final coating such as a wet or dry coating may be applied to the cured layers as a final coating or topcoat.

In another embodiment, one or more additional bonding material layers are applied to the first or primary bonding material layer applied to the surface of the substrate to meet specific design specifications or coating requirements of a manufacturer. The bonding material layers may be the same or different bonding materials and are applied to the first bonding material layer until a predetermined thickness is achieved. The uniform dry particles may be applied to any one of the reinforcing material layers on the surface of the substrate. Additionally, different materials may be added to the bonding material layer or layers, based on specific design specifications.

In a further embodiment, the coated substrate is cured using induction heating. In this embodiment, induction sensitive particles such as metal particles are applied to the wet bonding material on the surface of a substrate. The metal particles are rearranged in the wet bonding material using a magnet and induction waves, which are reverse magnetic fields, are then directed at the coated substrate to induce heat in the wet bonding material. The heat induced in the wet bonding material cures the wet bonding material. In another embodiment, an induction heat device is used to raise the temperature of the substrate and thereby cures the wet bonding material layer.

It is therefore an advantage of the present invention to provide a reinforcing underlayment and a method for manufacturing the reinforcing underlayment that increases the desired final system characteristics of a substrate.

Another advantage of the present invention to provide a reinforcing underlayment and a method for manufacturing the reinforcing underlayment that enhances, improves or changes the inherent characteristics of a substrate or surface.

A further advantage of the present invention is to provide a method for manufacturing for a coating underlayment which enables the underlayment to be applied to a substrate as a single, even and substantially uniform layer of particles.

Another advantage of the present invention is to provide a method of manufacturing a coating underlayment that employs substantially uniform particles to form the underlayment layer on a substrate.

A further advantage of the present invention is to provide a method of manufacturing a coating underlayment that employs different sized particles and particles of different chemistries and characteristics to form the underlayment layer on a substrate.

Another advantage of the present invention is to provide a coating underlayment and method of making the coating underlayment that can be used on a wide variety of temperature sensitive substrates and products.

A further advantage of the present invention is to provide a coating underlayment apparatus and method which significantly reduces capital equipment costs, operation costs and process complications.

Additional features and advantages of the present invention are described in and will be apparent from, the following Detailed Description of the Invention and the Figures.

BRIEF DESCRIPTION OF THE FIGURES

FIG. 1A is an enlarged fragmentary side view of a coated substrate of one embodiment of the present invention.

FIG. 1B is an enlarged fragmentary cross-sectional view of the coated substrate of FIG. 1A taken substantially along the line 1B-1B.

FIG. 1C is an enlarged fragmentary side view of a coated substrate of another embodiment of the present invention including angular particles distributed on the surface of the substrate with different densities.

FIG. 1D is a top view of the embodiment of FIG. 1C.

FIG. 1E is an enlarged fragmentary side view of a coated substrate of another embodiment of the present invention including spherical particles distributed on the surface of the substrate with different densities.

FIG. 1F is an enlarged fragmentary side view of a coated substrate of another embodiment of the present invention including flake-shaped particles distributed on the surface of the substrate with different densities.

FIG. 1G is an enlarged fragmentary side view of a coated substrate of another embodiment of the present invention including fiber particles distributed on the surface of the substrate with different densities.

FIG. 1H is an enlarged fragmentary side view of a coated substrate of another embodiment of the present invention including spherical and flake-shaped particles distributed on the surface of the substrate with different densities.

FIG. 1I is an enlarged fragmentary side view of a coated substrate of another embodiment of the present invention including spherical and fiber particles distributed on the surface of the substrate with different densities.

FIG. 1J is an enlarged fragmentary side view of a coated substrate of another embodiment of the present invention including fiber and flake-shaped particles distributed on the surface of the substrate with different densities.

FIG. 2A is an enlarged fragmentary side view of a coated substrate of a another embodiment of the present invention illustrating angular particles applied to the bonding material layer on the surface of a substrate.

FIG. 2B is an enlarged fragmentary side view of the embodiment of FIG. 2A where an abrasion resistant coating is applied to the angular particle layer on the surface of the substrate.

FIG. 3A is an enlarged fragmentary side view of a coated substrate of a another embodiment of the present invention illustrating different sized particles applied to the bonding material layer on the surface of a substrate.

FIG. 3B is a top view of the embodiment of FIG. 3A.

FIG. 3C is an enlarged fragmentary side view of a coated substrate of a further embodiment of the present invention illustrating different sized particles applied to the bonding material layer on the surface of a substrate.

FIG. 3D is a top view of the embodiment of FIG. 3C.

FIG. 4 is a flowchart illustrating one embodiment of the coating method of the present invention.

FIG. 5A is an enlarged fragmentary side view of a coated substrate of a further embodiment of the present invention illustrating flake-shaped particles applied to the bonding material layer on the surface of a substrate.

FIG. 5B is an enlarged fragmentary side view of a coated substrate of another embodiment of the present invention illustrating the wear pattern of ultra porous particles applied to the bonding material layer on the surface of a substrate and the attachment of the 80% worn particles due to the anchor pattern of attachment or bonding sites within the porous particles.

FIG. 5C is an enlarged fragmentary side view of a coated substrate of a further embodiment of the present invention illustrating ultra porous metal particles infused with smaller particles and a topcoat containing wear and friction reducing agents.

FIG. 5D is an enlarged side view of one of the infused ultra porous metal particles of the embodiment of FIG. 5C.

FIG. 6A is an enlarged fragmentary side view of a coated substrate of another embodiment of the present invention illustrating a coated substrate including a coating layer applied to the bonding material layer.

FIG. 6B is an enlarged fragmentary cross-sectional view of the coated substrate of FIG. 6A taken substantially along the line 6B-6B.

FIG. 6C is a top view of the embodiment of FIG. 6A.

FIG. 7A is an enlarged fragmentary side view of a coated substrate of a further embodiment of the present invention illustrating a coated substrate including multiple underlayment layers and dry particles in each individual layer.

FIG. 7B is an enlarged fragmentary cross-sectional view of the coated substrate of FIG. 7A taken substantially along the line 7B-7B.

FIG. 7C is an enlarged fragmentary side view of a coated substrate of another embodiment of the present invention illustrating a coated substrate including multiple underlayment layers having spherical particles introduced into each individual layer.

FIG. 7D is an enlarged fragmentary cross-sectional view of the coated substrate of FIG. 7C taken substantially along the line 7D-7D.

FIG. 7E is an enlarged fragmentary side view of a coated substrate of another embodiment of the present invention illustrating a coated substrate including multiple underlayment layers having angular particles.

FIG. 7F is an enlarged fragmentary cross-sectional view of the coated substrate of FIG. 7E taken substantially along the line 7F-7F.

FIG. 8 is an enlarged fragmentary side view of a coated substrate of a further embodiment of the present invention illustrating the uniform particles as substantially uniform round particles.

FIG. 9 is an enlarged fragmentary view of a coated substrate of another embodiment of the present invention illustrating multiple wet material bonding layers including hard and soft particles applied to the surface of the substrate.

FIG. 10A is an enlarged fragmentary view of an example of the coated substrate of FIG. 9 illustrating a stage of the process for forming the coating on the substrate.

FIG. 10B is an enlarged fragmentary view of an example of the coated substrate of FIG. 9 illustrating the final stage of the process for forming the complete coated substrate.

DETAILED DESCRIPTION Reinforcing Underlayment

Referring now to FIGS. 1A and 1B, one embodiment of a product including the coating reinforcing underlayment of the present invention is illustrated where a coating such as a topcoat material is applied to an underlayment. In this embodiment, a reinforcing underlayment 103 a includes a wet bonding material layer 104 a and a single layer of substantially uniform dry particles 106 a which are applied substantially evenly to the bonding material layer on a surface of the substrate or product as shown in FIG. 1A. The reinforcing underlayment of the present invention is employed or used to facilitate the adherence of a coating to at least a portion of the surface of the substrate. The substrate 102 a generally may be any suitable type of substrate such as a metal, wood, plastic, glass or other suitable material.

A layer of wet bonding material 104 a such as a separate layer of an adhesion promoter or other suitable material or mixture of materials, is applied to the surface of the substrate to be coated to promote the adhesion of subsequent layers to the substrate. In one embodiment, the wet bonding material is a ultraviolet light cure resin. In another embodiment, the wet bonding material includes an electron beam cure resin. It should be appreciated that the bonding material layer 104 a may be any suitable wet bonding material with or without one or more additives which change or enhance one or more characteristics of the wet bonding material. In one embodiment, the wet bonding material layer or film thickness ranges from five microns to one hundred fifty microns or larger. The wet bonding material layer may therefore be a thick layer where the uniform particles sink into and are completely covered by the wet bonding material layer. In another embodiment, the wet bonding material layer is a substantially thin layer on the surface of the substrate and only a small portion of the particles adhere to the thin, wet bonding material layer. Furthermore, the reinforcing underlayment 103 a includes a single layer of substantially uniform dry particles 106 a, which are evenly distributed or applied to the wet bonding material layer 104 a. After the dry particles 106 a are applied to the wet bonding material layer and the wet bonding layer is cured, a reinforcing material topcoat layer or reinforcing topcoat coating 108 a is applied to the reinforcing underlayment 103 a. The reinforcing topcoat coating 108 a may be any suitable type of material or coating applied to substrates such as a topcoat, paint, a corrosion protective coating or other suitable materials or coatings that can be mixtures of solid particles and liquid materials. It should also be appreciated that the reinforcing topcoat coating may be any suitable topcoat such as ultraviolet light cure resins or electron beam cure resins. One or more reinforcing material layers or reinforcing coatings may be applied to the layer of dry particles based on the design specifications and the desires of the manufacturer. The reinforcing material layers or coatings may be the same materials or coatings, or different materials or coatings. In one embodiment, the final topcoat reinforcing material layer(s) is/are applied to the dry particle layer until a predetermined or desired thickness is achieved. In another embodiment, the reinforcing material layers and/or coatings are applied until the layers and the substrate are a predetermined or desired total or overall thickness.

After the coatings have been applied to the substrate, the resultant structure of the underlayment 103 a includes the dry particles or granules introduced into the wet bonding material layer where the wet bonding material layer adheres to various types of surfaces of a substrate such as round or flat surfaces. In a curing process, the dry particles 106 a remain in place completely covering the wet bonding layer 104 a while the wet bonding material layer 104 a passes through phases until the dry particles and the bonding material layer are fused together as the liquid layer is cured. It should be appreciated that the bonding material layer 104 a and uniform dry particles 106 a may be partially cured or completely cured depending on whether single or multiple bonding material and dry particle layers are applied to the surface of the substrate.

Referring to FIGS. 1C and 1D, another embodiment of the present invention is illustrated where the coated substrate includes uniform size angular particles distributed with varying densities on the surface of the substrate. This type of distribution may be employed on products such as cooking equipment where greater abrasion resistance is desired in specific areas. For example, the denser distribution of particles is applied to the more abrasive areas to minimize the effects of the abrasion on the surface. In FIG. 1C, a bonding material layer 104 b is applied to the surface of the substrate 102 b. The angular particles 106 b are then applied with different distributions or varied densities on the surface. The particles are applied to a suitable thickness such as the thickness 103 b. A topcoat or final coating 108 b is applied if desired, such as PTFE. In one embodiment, the topcoat is a suitable solvent which is applied over the particles after the particles are applied to the wet bonding material. The capillary action of the solvents draws some of the wet bonding material up over the particles as the solvent evaporates to strengthen the bond of the particles to the wet material bonding layer. The final coated substrate 100 b therefore includes different densities of uniform particles as shown in FIG. 1D.

Referring to FIGS. 1E to 1J, different types of particles and different combinations of particles may be applied to the wet bonding material layer on the surface of the substrate. In FIG. 1E, different densities of spherical particles 106 c are applied to the wet bonding material layer. In FIG. 1F, different densities of flake-shaped particles 106 d are applied to the wet bonding material layer. In FIG. 1G, different densities of fiber particles 106 e are applied to the wet bonding material layer. In FIG. 1H, different densities of a combination of spherical particles 106 c and flake-shaped particles 106 d are applied to the wet bonding material layer. In FIG. 1I, different densities of a combination of spherical particles 106 c and fiber particles 106 e are applied to the wet bonding material layer. In FIG. 1J, different densities of a combination of flake-shaped particles 106 d and fiber particles 106 e are applied to the wet bonding material layer. It should be appreciated that any suitable combinations of the above particles may be applied to the wet bonding material layer depending on the end-use requirements and specifications.

The coating underlayment is primarily composed of substantially uniform dry particles, which form a single substantially uniform and substantially even layer on the surface of the substrate or product. In one embodiment where abrasive resistant surfaces are desired, the substantially uniform dry particles may be any suitable size or shape as desired by the manufacturer such as flat-shaped, flake-shaped, angular-shaped, cylindrical-shaped, oblong-shaped and leaf-shaped particles. Specifically, the substantially uniform dry particles are substantially the same in size and shape for several reasons, including so that the coating area or area of adhesion is maximized on the surface of the substrate. In one embodiment shown in FIG. 2A, angular particles 206 such as triangular shaped particles are used to create a rough surface on a substrate by applying the angular particles to the bonding material layer 204 on the surface of the substrate 202. In another embodiment, softer, less abrasive surfaces are created by using shaped particles such as spherical shaped particles. In a further example described in more detail below, combinations of different shaped particles are used on a surface of a substrate as shown in FIGS. 3A and 3B. Thus, uniformly sized or shaped particles or different sized or shaped particles may be applied to a surface of a substrate.

As indicated above, in one preferred embodiment, the wet bonding material layer and the substantially uniform dry particle layer are applied to the surface of the substrate until a desired thickness is achieved. In one presently preferred embodiment, the desired thickness is approximately 5 μm to 100 μm. Other suitable thickness ranges may be used as desired by the manufacturer. In FIG. 2B, an abrasion resistant topcoat or final coating 208 is applied to the angular particles 206. The abrasion resistant coating further enhances the abrasion resistant characteristics of the surface of the substrate.

In another embodiment, the substantially uniform dry particle layer is composed of substantially spherical particles, which creates a softer, less abrasive surface on the substrate. It should be appreciated that the particles may be spherical particles, substantially flat flakes, fibers or any suitable shape or combination of shapes as described above, which maximizes the surface area of the uniform particle layer. Additionally, the size of the dry particles may be changed as desired to accommodate different technical and coating requirements or specifications. In one embodiment, the dry particles include at least one relatively large particle and at least one relatively small particle. In another embodiment, the dry particles range in size such as from a sub-micron to approximately 125-150 microns.

The density of the uniform particles on the wet bonding material layer on the surface of a substrate may be changed or enhanced to strengthen the bond of the particles in the layer. In one embodiment, the particles are applied to the wet bonding material layer and then the part is vibrated to settle the particles into the wet bonding material layer. In another embodiment, a wet bonding material layer and a layer of substantially uniform particles are applied to a surface of a substrate such as a round part having an internal bore. The part is rotated, which causes the particles to densify or pack together in the wet bonding material due to the centrifugal force of the spinning part.

Referring to FIGS. 3A and 3B, the uniform particle layer includes different sized spherical particles 306 a and 306 b applied to the bonding material layer 304 on the surface of the substrate 302. In one example, the smaller sized particles 306 b are softer particles and the larger sized particles 306 a are harder particles such that the soft particles provide lower friction and the hard particles enhance the abrasion resistance of the surface as described in more detail below. Another example, hard abrasion resistant larger size particles and smaller electrically conductive particles are applied to create an abrasion resistant and electrically conductive reinforcement underlayer. A topcoat or final coating 308 of a suitable material is applied to the uniform particle layer. In FIGS. 3C and 3D, another aspect of this embodiment is illustrated where different sized angular particles 306 c and 306 d are applied to the wet bonding material layer 304 on the surface of the substrate 302. It should be appreciated that any sizes and shaped particles may be applied to the surface of the substrate.

Coating Underlayment Method

Referring to FIG. 4, one embodiment of the method of applying the coating underlayment to form a coated substrate is illustrated in the flow diagram. In the method illustrated in FIG. 4, one or more surfaces to be coated on a substrate are cleaned using a suitable cleaner as indicated in block 400. The cleaner removes a substantial portion of or all of the impurities that may be on the surface of the substrate which may inhibit the adhesion of one or more of the layers to the substrate. The surfaces to be coated may be cleaned manually or mechanically in an automated process. The substrate may be cleaned using any suitable cleaning process such as grit blasting or sandblasting, which slightly roughens and cleans the surface or surfaces of a substrate. Additionally, the substrate may be pre-cleaned in a clean room or similar manufacturing area where the step described in block 400 is not necessary.

After the substrate is cleaned or is clean, a layer of a substantially wet bonding material is applied to the substrate as indicated by block 402. The bonding material provides a wet or moist surface for the subsequent substantially uniform dry particle layer to adhere to. The wet bonding material may be any suitable bonding material, which meets the specific design specifications of the particular product or substrate. In this embodiment, it is important that the bonding material remain wet prior to the application of the uniform dry particle layer so that the dry particles stick to or adhere to the wet bonding material. As described in block 404, in this embodiment, a single layer of substantially uniform dry particles are applied or sprayed onto the wet bonding material layer until the wet bonding material layer is completely coated with the dry uniform particles and a desired thickness is achieved. The thickness of the coatings or coating layers is dependent on the specifications for the particular product, the amount of bonding material applied and the size and shape of the dry particles.

In one embodiment, the substantially uniform dry particles are sprayed or applied onto the wet bonding material as a single substantially uniform and substantially even layer which adheres to the sticky or wet surface of the bonding material. In another embodiment, the substrate is electrically grounded using a suitable grounding method. Grounding the substrate thereby grounds the wet bonding material layer, which is formulated to include solvents and/or liquids that conduct electrical energy. The substantially uniform dry particle layer has or will have an opposite electrical charge to that of the bonding material layer and therefore is electrically or electrostatically attracted to the wet bonding material layer as the dry particles are applied to that layer. In a further embodiment, an applicator such as a sifter is used to uniformly apply the uniform particles to the wet bonding material layer. The sifter is similar to a conventional flour sifter or a drum sifter and is used in certain applications depending on the required application of the uniform particles.

In another embodiment illustrated in FIG. 5A, an electrically conductive liquid bonding material layer is applied to the surface of the substrate to enhance the attraction of the dry particles, which may be material flakes (as shown in FIG. 5), ceramic or plastic particles and also specially treated or untreated particles, such as bronze, brass, zinc, copper, steel, stainless steel, aluminum, graphite, titanium, molybdenum disulfide, molybdenum, talc, lead, antimony, tin, silver, titanium and nickel or any other suitable metals, alloys, ceramics or plastics. The oppositely charged or tribo-charged (i.e., friction charged) electrical attraction of the dry particles or flakes 506 to the wet bonding material layer 504 promotes the adhesion and uniformity of coverage of the dry particles to the bonding material layer. The metal particles can be propelled toward the wet surface with air or gasses that have been ionized or treated to momentarily electrically charge the metal conductive particles with the opposite charge of the wet surface of the substrate. The result is a dense, substantially uniform and evenly distributed particle layer or underlayment layer on the surface of the substrate 502.

In another embodiment, a liquid bonding material layer such as an epoxy, which is thermally cured, is applied to the surface of the substrate. The metal particles are then introduced using a dry powder spray mechanism. In one aspect of this embodiment, the metal particles are passed through a heating chamber or flame device, such as on a metal spray gun. The metal particles pass through an oxyacetylene flame raising the temperature of the particles as the particles are propelled towards the pre-applied wet bonding layer. Introduction of heat into the particles allows the wet bonding material layer to start curing or semi-curing. The curing or semi-curing occurs because the heat introduced into the coating starts to harden the bonding material layer after the particles have been immersed in the material layer due to the velocity and force of the particles propelled at the wet bonding material layer.

In a further embodiment, several different metals are applied to a bonding material layer on a surface of a substrate. In one example, bronze particles having a size of 35-microns and lead particles having a size of 5-microns are sequentially applied to a bonding material layer on a surface of a substrate. In another example, metals and non-metals are combined to form the underlayment. For instance, bronze particles and pre-cured imide-amide particles can be applied to the bonding material layer. Additionally, particles formed from a material from the imide family and particles formed from another family such as high-end imides can be applied to the bonding material layer. This combination allows the bronze to dissipate or absorb surface heat and conduct heat away from the surface of the substrate. The engineering plastic materials described above can be used instead of the bronze particles if much lower friction is desired.

Referring now again to FIG. 4, after the substantially uniform particle layer is applied to the bonding material layer, the layers are cured to strengthen the bond between the uniform dry particle layer and the wet primer layer on the surface of substrate as indicated by block 406. The curing process may be performed by heating the layers at a predetermined temperature or temperatures, air-drying the layers or by utilizing any suitable internal or external curing or cross linking process. In addition, the curing process may use a single or plural package heat cure or air-dry materials, such as polyimide for heat cure applications and acrylics for air-dry applications and two part epoxies for room temperature or U.V. rapid curing. When the substantially uniform dry particle layer has completed adhered or bonded to the bonding material layer, a suitable coating layer is applied to the uniform dry particle layer as indicated in block 408. The coating may be any suitable coating such as a topcoat or final coat material. Examples include corrosive or abrasive resistant coatings, non-stick coatings or low friction coatings and electrically insulative or conductive coatings or combinations thereof.

The substantially uniform dry particle layer maximizes the surface area exposed to the coating applied to that surface of the particles. Increasing the surface area for the application of a coating to that area, enables the coating to develop a very strong mechanical bond to the underlayment layer and ultimately to the substrate. The strong bond between the coating and the underlayment layer promotes the durability and strength of the coating on a product or substrate. Furthermore, the coating underlayment layer also promotes a substantially even and uniform distribution of the coating to the substrate. Optimum adhesion is provided by the first wet bonding layer on the surface to the subsequently applied particles. The second wet coating is formulated to provide optimum adhesion to the particles and provide specific characteristic to the final surface as determined by the use of the final surface. This minimizes the defects or uneven distribution of the coating on the surface of the substrate and promotes the maximum functional values of the coated part. Thus, less parts or products are discarded due to uneven coating or defective coating layers on a substrate or product and the coating provides the maximum functional characteristics with minimal compromises of the functional characteristics of the finished or complete coating.

Uniform Particle Embodiments

The types of particles applied to the surface of a substrate vary based on the specific requirements of a substrate or based on the environment in which the substrate is being used. In one embodiment, dry or powdered carbon particles or whiskers such as carbon fiber particles or whiskers are applied to a substrate to prevent wear of a surface on the substrate and to provide a non-metallic conductive surface. The dry or powdered carbon fibers are substantially uniform fibers applied to a wet bonding material layer such as a primer on a surface of a substrate. In one example, a substrate including carbon fiber particles is used for high temperature commercial knives and cutting blades where static electricity must be dissipated. In another example, a substrate including carbon fiber particles is used for conveyors to transport paper and other static electricity producing materials, such as plastic. In this embodiment, the wear reduction capabilities of a substrate are vastly improved with the carbon fibers, which can be as small as approximately three microns in diameter and approximately 20-30 microns long. When the carbon fibers are dry sprayed onto the bonding material layer, the shorter fibers orient themselves in multiple directions thereby enhancing the wear resistance of the carbon fiber layer (the end of the carbon fiber particles do protrude through the final coating surface). The bonding matrix is designed according to end use or design specifications. The carbon fibers may include a high or low temperature material.

In another embodiment, aramid fibers or engineered plastic particles or fibers are applied to a substrate to strengthen the surface of the substrate. The aramid fibers may any suitable aramid material such as Kevlar®, which is manufactured and sold by the E.I. du Pont de Nemours Company. The aramid or Kevlar® fibers are applied to the bonding material layer in very much the same manner as the carbon fibers or whiskers. The Kevlar® fibers or materials can be either a pulp, which includes loose, fluffy fibers which is further ground into a fine powder, or can be other suitable forms such as round particles or semi-round particles. The aramid particles provide non-metallic wear resistance and have good bonding ability with both the basecoat and subsequent topcoats. Thus, the applied aramid fibers or materials create a dense layer of aramid or Kevlar® particles on the surface of the substrate, which is then coated with a topcoat or other suitable final coating. However, if a very high temperature non-metallic or non-ceramic, moderate friction (i.e., low abrasion) surface is desired, a topcoat or final coating is not applied to the layer of aramid fibers as in a brake surface or clutch facing, or a specific high temperature topcoat formulation may be applied as an option.

In another embodiment, individual and/or combinations of aramid fibers or particles, which may be any random shape and size, are applied to the surface of the substrate. In this embodiment, the dry aramid particles or fibers are applied to the wet bonding layer, which has been previously applied to the surface of the substrate. Because the aramid fibers have extreme temperature resistance compared to most polymers and organics, the aramid fibers or particles can be topcoated with a very high temperature PTFE or silicone type resin. Therefore, the temperature resistance, non-stick capability and wear resistance of the final coated surface is equivalent to and sometimes greater than the same properties for metal fibers or particles.

In one example, the aramid fibers are used as a clutch facing or in a braking mechanism in a tightly contained space. In this example, an aluminum brake shoe is pre-coated with a wet silicone or high temperature imide-amide material layer, then a layer of aramid fibers or particles, followed by another wet silicone or imide-amide layer, and then a imide-amide particle material layer. In one example application of the present invention, a motorcycle clutch disc is manufactured of aluminum and then, using this method to provide wear resistance, eliminates the steel clutch disc construction and reduce the weight of the clutch assembly by more than fifty percent. The aramid fibers reduce and prevent galling and seizure of counter surfaces because of the aramid fibers extremely high temperature capability and ability to char and ablate at the outer surfaces in the presence of oxygen and high scuffing at relative speeds. Additionally, a thin topcoat of PTFE, graphite or another suitable lubricant film can be applied to the aramid particle layer to assist the break in of the counter surface or surfaces.

In a further embodiment, specially treated, uniform plastic particles are applied to a wet bonding layer as applied to a substrate. The plastic particles are pre-treated PTFE, UHMW and/or polyethylene (PE) or another suitable material and applied to the wet bonding material on the surface of the substrate. The particles are pre-irradiated or processed with an electron beam or other suitable method which causes the particles to be able to sink into the wet bonding material layer, instead of remaining on the top of the wet material bonding layer. Therefore, the plastic particles are strongly bonded to the layer and not easily dislodged from the surface. This process thereby enables the plastic particle layer to last longer.

In another embodiment, dry or powdered anti-microbial particles which reduce and kill bacteria and other microbials are applied to the wet bonding material layer on the surface of a substrate. In one aspect of this embodiment, a final coating or topcoat is not applied to the dry anti-microbial particles or powder layer, which enables the anti-microbial particles to remain at the surface. In another aspect of this embodiment, a thin topcoat or final coating such as polytetrafluorethylene (PTFE) is applied to the anti-microbial particulate layer to perform a release function such as a non-stick coating on the surfaces of cooking equipment. In one example, a counter top such as a kitchen counter, is coated with a two part epoxy followed by a powder coating of anti-microbial material. Then, a thin coating of the epoxy is applied to the anti-microbial particulate layer as a final coating or topcoat. Such a counter may be used in a meat packing plant to kill harmful bacteria on counters where the meat is cut and packaged or the anti-microbial coating may be used on hooks or similar conveying equipment in a meat packing house. The anti-microbial effect of the coatings on the counters can be maintained by repeating the coating process on the counter surfaces periodically as needed. It should be appreciated that any suitable anti-microbial particles or material such as silver, silver-ceramic or silver compounds may be used in the above embodiment.

In a further embodiment, dry or powdered, ultra porous bronze or other porous particles are applied to the wet bonding material layer on the surface of a substrate. The ultra porous bronze particles are “sponge-like” particles that include many openings and voids such that the particles are approximately seventy percent solid compared to over ninety percent solid for other porous bronze materials. The ultra porous bronze particles are infused with the wet bonding material after the bronze particles are deposited on the wet bonding material on a surface of a substrate. The infused or vacuum infused material layer permeates the pores of the bronze particles and bonds to the “mini-tunnels” in the particles. The infused layer adds lubrication and increases the bonding strength of the layers to hold the bronze particles to both the upper and lower coating layers and to the surface of the substrate. Thus, this process “locks” the ultra porous particles into the wet bonding material layer, which prevents the particles from dislodging easily from the wet bonding material layer as they wear.

FIG. 5B illustrates the secure bond of the ultra porous particles in the bonding material layer. The ultra porous particles are applied to a wet bonding material layer 510 on the surface of a substrate 508 as described above. In addition, a topcoat or final coating 513 of a suitable material such as PTFE is applied to provide further wear resistance. In FIG. 5B, Section I shows that initially one hundred percent of the ultra porous particles are applied to the wet bonding material where there is zero percent wear of the particles. After the topcoat 513 is completely worn away and after the ultra porous particles are worn down to approximately fifty percent of the particles original size as shown in Section II of FIG. 5B, the particles still strongly adhere to wet bonding material 510. As shown in Section III, after some additional time, almost all of the particles remain adhered to the bonding material layer even after approximately eighty percent of the particles has been worn away. In one embodiment, a special topcoat layer including a high solid material which migrates into the pores of the attached bronze particles is applied to the particles, either after the first curing process or as part of the first bonding material layer applied to the surface of the substrate.

In another embodiment, porous metal particles such as the bronze particles described above are impregnated or infused with a material such as PTFE, which lowers the friction of the particles. In one aspect of this embodiment, bronze particles defining or including seventy percent voids (i.e., air) is vacuum impregnated with a suitable material such as PTFE. In another aspect of this embodiment, the bronze particles are soaked with the PTFE and the dried. The latter process leaves partial voids in the particles where the particles are approximately forty percent solids. It should be appreciated that any suitable metal or metal alloy or ceramic particle or particles may be used as the base particles. It should also be appreciated that any suitable low friction material such as PTFE, anerobic polyester and UHMW may be used to fill or partially fill the voids.

Referring to FIGS. 5C and 5D, in another embodiment, a topcoat material 526 including lubricative particles 527 is applied to the ultra porous bronze particles 524 in the bonding material layer 522 on the surface of a substrate 520. The applied lubricative particles 527 infuse the voided centers 525 of the ultra porous bronze particles to enhance the lubrication associated with the particles and reduce the friction on the particles. The lubricative particles 527 may contain PTFE, graphite or any suitable non-abrasive and/or non-stick material. It should be appreciated that the porous particles may be any suitable porous metal particles such as stainless steel particles, nickel particles, bronze particles, iron particles, titanium particles and suitable particles including a metal and/or metal alloys and also porous ceramic particles which can be infused with conductive particles such as carbon.

Additional Material Layers

In a further embodiment, catalyzed bonding materials such as epoxies and urethanes are used in the present method to enhance the bond strength and lower the curing temperature of the coatings. These bonding agents will be tailored to the desired end use characteristics and also to the temperature capabilities of the substrate. In one example, the flexibility of cure temperature and bond strengths is demonstrated by the bonding of pure bronze particles to a commercial glass-filled plastic engineering component, such as a sliding block contact in an electrical switch gear. The lightweight, rigid engineering glass reinforced plastic conducts no electricity. By adding a layer of bronze, copper, and silver in successive layers, an impact-resistant material is created which contacts a switch gear and makes electrical contact. This may be used, for example, for a safety switch, where the safety switch must be very light weight to respond mechanically quickly in a safety situation. This embodiment may also be employed in a radio wave and electromagnetic environment to absorb radio frequencies (RF) and electromagnetic waves.

In another embodiment, acid or chemical resistance is increased by applying a protective, non-metallic, non-plastic material such as dry ceramic, glass, mica flakes and/or mica particles to the wet bonding material layer. The dry ceramic or mica flakes and/or particles create a barrier or a substantial barrier to an acid or other chemical. The non-metallic, non-plastic material may be any suitable materials such as ceramics, glass, modified mica, mica, boron nitride, silica nitride and aluminum oxide. The barrier diverts the acid or chemical by creating a torturous path or a maze-like path which the acid or chemical cannot avoid as it attempts to penetrate the protective coating. Therefore, the acid or chemical is prevented from directly attacking a base material such as a metal, by decreasing the inherent permeability and porosity of a base coating or coatings such as a fluoropolymer based acid resistant coating.

Referring to FIGS. 6A, 6B and 6C a further embodiment of the present invention is illustrated where a coated substrate 600 includes one or more additional wet bonding material layers applied to the primary or first wet bonding material layer based on specific design specification or manufacturer requirements. The bonding material layers are applied to the first bonding material layer prior to applying the layer of substantially uniform dry particles. In one embodiment, the additional or subsequent bonding material layers include different bonding materials. In another embodiment, the layers include the same bonding material, which is applied to the first bonding material layer to a desired thickness, such as a thickness, t. First, a desired substrate 602 such as a metal substrate is first determined by the manufacturer. Then, the first bonding material layer 604 is applied to the surface of the substrate 602. A second or additional bonding material layer 605 is applied to the first bonding material layer 604. The layer of substantially uniform dry particles 606, which are substantially uniform in shape and size, is applied onto the second bonding material layer or top bonding material layer. The thickness of the subsequent bonding material layers applied to the substrate are generally predetermined according to a design specification or manufacturer requirements. A suitable topcoat or final coating layer 608 is applied to the uniform particles to achieve the final coated substrate. It should be appreciated that the thickness of the bonding material layers or coatings on the substrate or the thickness of the overall substrate may vary according to the design specifications. Thus, the final coated product or substrate 600 may be any suitable thickness or composition. Additionally, it should be appreciated that other suitable material layers may be applied to the wet bonding material layer based on specific design specifications or requirements. The material layers may include the same or different materials.

In FIGS. 6B and 6C, the dry particles 606 are uniformly distributed on the material bonding layer or primer layer 604 so that the dry particles 606 are dense and cover every facet of the surface on the primer layer. By using a single layer of substantially uniform dry particles, the topcoat adheres to the maximum surface area of the particles and thereby develops an extremely strong bond between the coating layer and the particles 606 of the underlayment 603 a. In one embodiment, a single, substantially uniform dry particle layer 606 is applied to a substrate to promote the adhesion of a coating to the substrate or product. In another embodiment, the method of coating a substrate using the underlayment as described above, may be repeated to apply multiple reinforcing coatings or reinforcing material layers such as multiple topcoatings to the substrate. In this embodiment, the reinforcing material layers are applied until a desired thickness is achieved. The desired thickness may be any desired thickness or suitable thickness predetermined by the manufacturer. Thus, the present embodiment of the underlayment may be used to apply multiple reinforcing coatings or reinforcing material layers to a single substrate and to multiple surfaces on a substrate.

Referring to FIG. 9, in another embodiment, a wet bonding material layer 904 a including relatively small particles 906 b of a suitable low friction or soft material such as PTFE or UHMW is first applied to the surface of a substrate 902 as shown in the left section. Next, a layer of uniform hard dry particles 906 a such as bronze particles or other suitable hard particles is applied to the wet bonding material layer. Then another layer of the initial wet bonding material mixture 904 b including the relatively smaller particles is applied to the dry particle layer as shown in the middle section. The layers are dried and dissolved using a suitable curing process or other suitable drying process. This causes the top layer or second wet bonding material layer including the small soft particles to shrink and distribute the small soft particles amongst the hard bronze particles as shown in the right section. This creates an abrasion resistant and low friction surface.

Referring to FIGS. 10A and 10B, in another embodiment, an initial wet bonding material layer 1003 including relatively small silver plated copper flakes 1007 and spherical copper particles 1004 are applied to a surface of a substrate 1002. Then, a second wet bonding material layer 1006 including the same mixture of smaller silver-plated copper particles is applied to the surface. A solvent layer 1008 is then applied as a topcoat or final coating on the two wet layers. The layers are then dried using a suitable drying or curing process. This dissolves the solvent layer as shown in FIG. 10B, and partially dissolves the second or top wet material bonding layer to smoothen and sink the silver plated copper flakes and copper particles in the initial wet bonding material layer. The resultant surface includes hard metal particles which resist abrasion while the softer small particles reduce friction on the surface.

Multiple Underlayments

Referring now to FIGS. 7A and 7B, multiple underlayments, such as underlayments 703 a, 703 b and 703 c, are applied to a surface of a substrate. The underlayments are applied to create a thicker film on the substrate based on desired design specifications or other suitable design requirements of a manufacturer. Two or more underlayments 703 may be applied to the surface of the substrate. In FIGS. 7A and 7B, in one example, a substrate 702 is first coated with a first layer of a wet bonding material 704 a. A first substantially uniform layer of dry particles 706 a is applied to the first bonding material layer 704 a. A second bonding material layer 704 b is then applied to the first layer of dry particles 706 a. Then, a second substantially uniform layer of dry particles is applied to the second bonding layer 704 b. A third bonding material layer 704 c is applied to the second uniform layer of dry particles 706 b. A third layer of substantially uniform dry particles 706 c is applied to the third bonding material layer 704 c. The combination and thickness of the layers or film is determined by the desired design specifications for the layers on the surface of the substrate. A suitable topcoat or final coating material 708 is then applied to the final uniform particle layer 706 c. It should be appreciated that any suitable thicknesses or coating layer or layer combinations may be applied to the surface of a substrate.

Referring to FIGS. 7C and 7D, another example of the embodiment illustrated in FIGS. 7A and 7B are illustrated where the multiple underlayments include substantially spherical particles 706 a, 706 b and 706 c. In FIGS. 7E and 7F, the particles 706 a, 706 b and 706 c are angular particles which are applied in the underlayment layers. It should be appreciated that any suitably shaped uniform particles may be applied to the wet bonding material layers based on the design specifications and end-use criteria.

In the alternative embodiments of the present invention, if wear resistance is required, then the second layer or layer of substantially uniform dry particles is generally the final layer applied to the surface of a substrate. If non-stick or high corrosion resistance is required, then a third and/or fourth wet coating layer or topcoat including a suitable non-stick material or similar material is added to the above layers to increase the non-stick characteristic of the surface of the finished, coated substrate.

Several different types of additives may be added to the topcoat or final coating to improve the performance characteristics of the coated substrate. In one embodiment, a counterface or opposing surface smoothening additive including relatively hard, relatively smaller particles, is added to a topcoat or final coat, to enable the coated substrate to smoothen or polish a rough surface or surfaces, which contact the surface of the coated substrate. In one example, when rough metal surfaces rub against PTFE coated substrates, the PTFE wears away. Quickly, this diminishes the quality and performance of the PTFE on the coated substrate. To remedy this problem, a smoothening additive is added into the wet topcoat of PTFE so that the topcoat or outer layer on the surface of the substrate contains harder particles than the counter surface such as a metal surface. The relative motion between the surface of the coated substrate and the rough metal surface (i.e., the interface), causes the additive particles to disperse as the particles wear away, and also polishes or smoothens the opposing surface of relatively rough metal so that the PTFE topcoat is not worn away prematurely. This also enables the layer below the topcoat to have a smooth counter surface to work against. It should be appreciated that any suitable additive may be added to the topcoat or final coating to improve the performance or desired characteristics of the coated substrate.

EXAMPLES

The above embodiments may be employed in several types of coating processes. In one example, a soft coating, which is commonly used to coat surfaces of cooking equipment, is applied to one or more surfaces of a substrate.

The surface is prepared with cleaning and/or grit blasting to uniformly roughen and clean the oxide layer off the surface, whether it be aluminum, aluminum oxide, steel, glass, ceramic, plastic or any suitable material. A primer bonding mixture or solution including a wet layer of a polyamide-imide (PAI) material is solvated in or dissolved in a solvent comprising a resin such as N-methylpryrrolidine (NMP) is sprayed onto the surface of the substrate so that the thickness of the wet mixture or solution is approximately between 30-50 microns thick. Alternatively, other suitable application methods such as dipping the substrate into the solution or flowing the mixture or solution onto the surface of the substrate may be used to apply the solution to the surface of the substrate. The solids in the PAI is approximately fifteen percent and solids in the NMP vehicle is approximately eighty-five percent. Dry particles or granules of aluminum oxide are then applied to the bonding layer. Preferably, the aluminum oxide particles protrude through and are held by the bonding layer. The particles in this example are approximately 50-60 microns in size which, when the bonding layer shrinks because it is comprised of eighty-five percent solvent and fifteen percent PAI resin, leaves a rough surface not unlike commercial sandpaper. The exception is that each particle has been completely coated with the diluted primer bonding mixture.

In this example, the dry particles are completely coated with the primer bonding mixture because the dry particles are one hundred percent solids, where the primer bonding mixture is primarily a liquid including approximately twelve to twenty-five percent solids. As the liquid bonding material shrinks, it adheres the particles to the substrate through adhesive bonding of the amide-imide to the substrate to itself and to the introduced particles. The resultant underlayment is cured at approximately 300-600 degrees Fahrenheit, depending on the subsequent coating or coatings, if any, which may be applied to the underlayment.

In another example, an amide-imide (AI)/PTFE primer or intermediate compatible material layer, which is compatible with and bonds to the amide-imide layer is applied to the substrate. In this example, the material layers are not cured. However, in one embodiment, a semi-cure of 400 degrees Fahrenheit is used after this phase to cure the layers on the substrate. A relatively pure PTFE coating dispersed in water and some added component of NMP is applied on top of the intermediate PTFE-AI layer. This last coat is flash dried at approximately 200 degrees Fahrenheit until all the water is removed. What remains is the aluminum oxide material held to the surface by, at the bottom of the particles near the substrate, a pure layer of PAI. The next layer still covering the dry aluminum oxide particles includes the intermediate or primer layer of the PTFE topcoat. In one embodiment, the PTFE topcoat has a thickness of approximately 10-15 microns. The intermediate PTFE-PAI coating is in a dry state and has a thickness of approximately 10-20 microns. The purpose of this method is to cover the largest particles of aluminum oxide to approximately 10-15 microns with a PTFE-rich topcoat. The resulting system is passed through an oven with temperature zones of approximately 400 degrees in a first phase to approximately 600 degrees to approximately 800 degrees in a third phase. At approximately 400 degrees, the remaining NMP in the basecoat comes through the liquid layers and helps to unify the bond of all three original liquid layers all of which contain amide-imide (AI). At approximately 600 degrees Fahrenheit, all of the volatiles and solvents are removed by heat evaporation, along with any wetting agents. At approximately 800 degrees Fahrenheit, the PTFE sinters to itself, the amide-imide bonds to the substrate and to the PTFE with a very high bond strength, and the dry aluminum oxide particles are held together by both the lower layer and the intermediate layer of AI coating.

In the above example, wear of the PTFE, which is soft and has non-stick properties, is substantially minimized on the surface of the substrate. Over time, the PTFE layer is worn away until the wear-producing object or objects contact the aluminum oxide layer, which has a substantial hardness of nine on a Mohs' scale. This near-diamond hard material includes jagged peaks as its particulate shape is very angular and multi-faceted. As the entire system is worn, only the peaks of the dry aluminum oxide layer stick through and support each other during the bonding of the lower and intermediate layers. The strength and hardness of the aluminum oxide layer prevents the PTFE from being worn away easily as the rough “mountains” or peaks of aluminum oxide have surrounding “valleys” filled with PTFE, which is protected by the aluminum oxide “mountains.” In fact, the aluminum oxide layer must be worn away before the PTFE is able to be worn away. The chemical and mechanical bonds of the PTFE layer to the intermediate and lower layers are so strong that the layers are not dislodged even from substantial cavitation pressures or hydraulic pressures. Essentially, the entire underlayment is locked or secured together. In one embodiment, the quantity of PTFE at the surface is reduced as wear takes place. However, even the partially worn underlayment remains effective as a non-stick layer such as a food contact release when the underlayment still includes approximately 50% PTFE. The PTFE remains effective because the low surface energy of the remaining PTFE layer repels any sticky or substantially sticky products. It should be appreciated that other suitable ceramic or metallic materials including non-stick or lower surface energy characteristics may be employed in the above embodiment instead of aluminum oxide.

In another embodiment, the shape of the dry particles or granules is changed such as to a rounder or spherical particle in a wear resistant application so as to minimize wear or “scratching” of an opposing surface. Additionally, using softer or harder ceramic materials or particles reduces the wear or scratching of the opposing surface or surfaces. As a result, the underlayment can be used in several different applications or products such as on the bottom of a frying pan, which has little or no PTFE.

In a further embodiment, higher temperature, rigid imide resins of particle sizes similar to those of aluminum oxide, approximately 40-60 microns, are used to make an even tougher system including no ceramic material and with a more cushioning or softer effect on the opposing counterface or surface. In one example, a conveyor for transporting glass could be processed using the non-ceramic underlayment particles and provide extraordinary wear yet very slippery surfaces that will not scratch the glass surfaces transported on the conveyor.

In a further example, the amide-imide is used as a bonding material or primer in the underlayment. Also, round bronze dry particles that can be solid or porous, are used in the underlayment instead of abrasive, angular particles. As a result, the underlayment provides wear resistance and reduction in an oil-wetted or oil-containing environment, such as in an automobile shock absorber. Additionally, other automobile parts including wear surfaces such as the rod guide and the wear band on a piston, can be manufactured using the underlayment of this embodiment. Furthermore, graphite, molybdenum disulfide or other additives can be added to the intermediate layer and/or upper coating or topcoat layer to improve the lubrication characteristics of the automobile or appliance parts or other similar parts or products. In the above embodiments, the dry bronze particles are covered by a PTFE or PTFE/resin material including wear-reducing agents such as molybdenum disulfide, graphite, talc, or particles of lead, zinc, antimony, tin, titanium or any other suitable material. Thus, the above embodiments may be used for commercial sliding tables, machine tools, automobile parts and other similar applications to enhance the wear resistance and load carrying capacity and still minimize the friction on the PTFE or PTFE containing intermediate and topcoat layers.

Different Sized Particles

Referring back to FIG. 3 in another embodiment, two different sized particles are applied to a substrate 302 to further enhance the wear-reducing capabilities of a surface of the substrate. The bonding material layer or primer layer 304 is applied first to the surface of the substrate 302, and then several large, dry metal particles 306 a such as 125-micron bronze particles are applied to the bonding material layer. Then smaller metal particles 306 b such as 25-30 micron lead particles are applied to the initial metal particle layer as an intermediate coating layer or as a topcoat layer. The underlayment of this embodiment therefore provides different wear characteristics based on the different counter surfaces and surfaces of a substrate or substrates.

Referring now to FIG. 8, another embodiment of the present invention is illustrated where the underlayment includes a single uniform layer of substantially spherical or round, dry particles 806. The spherical particles are substantially uniform in size and shape and are applied to a bonding material layer 804 on a surface. A suitable topcoat or final coating 808 is then applied to the uniform particles. The uniform size and shape of the spherical particles promotes the increase of the surface area for a coating to bond to the particles and also reduces the relatively soft particle coating wear rates. It should be appreciated that any substantially uniform size or shaped particles may be employed in the present invention to form the underlayment.

Coating Application Methods

In further embodiments, the coatings are applied using different application methods, which change the structure or bonding strength of the underlayment. In one embodiment, one or more suitable solvents or solvent-catalyst blends are sprayed or applied to the bonding material layer on the substrate simultaneously with the substantially uniform particles. The resultant spray or application method appears as a type of atomized spray, which enables the process to more completely wet the surface of the substrate. This process creates an even stronger bond between the bonding material layer and the uniform particles.

In another embodiment, a powder spray process is used, which enables an operator to better control the application of the layers to the substrate. The powder spray process applies the uniform particles as very fine particles to the lower layers adhered to the surface of the substrate. This process enables an operator to control the density of each of the layers applied to the substrate and also enables the operator to coat odd-shaped substrates with more control and accuracy. In a further embodiment, the electrostatic powder spray is used to apply a topcoat such as a powder paint coating or fluoropolymer powder coating to the surface of the substrate. In this embodiment, a bonding material and then a conductive material or coating is applied to the surface of the substrate. The powder coating is then cured in a convection or infrared oven, and because the powder coating does not include solvent, the heat from the oven heats and shrinks the powder coating onto the top of the dry particles. This type of topcoat may be used in many different industrial applications such as to produce electrical characteristics or increasing abrasion resistance of commercial bakeware and cookware.

In a further embodiment, electrostatic, tribo-charged or opposite electrostatic charged powder technology is used to further enhance the dry particle attachment or adherence to an odd-shaped configuration. The dry particles may be electrically insulative, but treated with a veneer of very thin conductive or insulative materials, such as the materials sold by the Ransburg Corporation, for creating electrostatic properties on substrates such as wood. In one embodiment, the dry particles are “soaked” with these electrostatic enhancing coatings or materials and subsequently dried or applied in a wet state with more conventional spray gun technology designed for wet materials. If the harder particles are ceramic and the configuration is very odd and angular, such as a fan housing or fan blades, electrostatic powder technology enhances the distribution of the dry particles. The bonding material layer or primer is altered to provide maximum electrical grounding potential by using solvents that are electrically conductive and contain water in some cases. This provides the maximum attraction of the dry particles to the bonding material layer, which provides a uniform, dense coating as desired by the application in all areas of a vessel or industrial component, such as a fan blade as shown in a centrifugal fan or turbine.

In the tribo-charging process, the tribo-charging is accomplished by stripping the electron off a particle of powder. This is accomplished by passing the particle over an opposite charged material that strips the electron off which is passed to ground or earth. This is commonly used by passing nylon particles through PTFE tubes by using air pressure to move the nylon particles at high surface speed over the PTFE surface. The opposite holds true. If PTFE particles are passed over nylon surfaces, they lose the outer layer of electron charge and are attracted to ground or a grounded article or surface.

In another embodiment, the wet materials can be introduced with conventional spray or electrostatic spray technology to apply the bonding material layer or primer to a surface of a substrate. In one example, a shaft, on which a wet bonding material layer is applied, is rolled over an electrostatic, aerated, fluidized bed of approximately 100,000 volts passing through an electrostatic grid with the dry particles suspended over a porous membrane of polyethylene. When air pressure is introduced underneath the electrostatic grid in an open top container, the dry particles become charged by the air passing through and past an electrical grid, which is placed slightly below the insulated polyethylene membrane. The charged dry particles above the porous polyethylene membrane are uniformly attracted to the wet substrate on the surface of the shaft, which is suspended and rotated above the fluidized bed. Because of the self-limiting characteristics of the electrostatic method, the dry particles are uniformly applied as the particles are applied to the substrate. The applied dry particles, as the particles are deposited, create an insulated layer in the areas where the dry particles are attached or attracted to the wet bonding material layer. This method provides a very uniform application of the dry particles to the surface of the substrate at high speeds and at low commercial costs.

In a further embodiment, the substantially uniform aluminum oxide particles are applied to a surface of a substrate to achieve a desired roughness on the surface. The desired surface roughness is achieved by changing the size of the aluminum oxide particles applied to the surface. The aluminum oxide particles are applied to a thin bonding material layer on a surface of a substrate and create a very strong bond with the surface of the substrate. The aluminum oxide particles may be applied to various surfaces including the surfaces of rigid parts. The application of the aluminum oxide particles to roughen the surface or surfaces of a substrate substantially minimizes the distortion to the surface, which occurs with conventional blasting methods, and enables a user to control the roughness of the surface. In addition, harder particles such as boron nitride particles or other suitable particles can be applied to the surface of the substrate to increase the penetration resistance of the surface.

Selective Application of the Uniform Particles

The wet bonding material layers are generally applied to the entire surface of a substrate. In one embodiment, the uniform particles are applied onto the entire wet bonding material layer. In another embodiment, the uniform particles are applied to specific areas on the wet bonding material layer on the surface of the substrate. In this embodiment, a mask of a suitable masking material is applied to the wet bonding material layer to prevent the adherence of the uniform particles to the masked areas. Thus, a surface of a substrate such as a particular surface or portion of a surface of a part can be masked or selectively coated with a suitable masking material so that the dry uniform particles are applied to specific areas of the surface of the substrate. In one example, specific surfaces of a cooking pan such as a sauté pan or wok are selectively coated with a non-abrasive and/or non-stick material to reduce abrasion and wear on those surfaces of the pan. A metal utensil is commonly used to stir or mix food products in the pan, which causes abrasion of the surfaces of the pan. The abrasion is generally focused on the bottom surface of the pan and not the side surfaces because the bottom surface of the pan gets hot causing the food products to stick to the bottom surface. Efforts of a user to dislodge the food product from the bottom surface using a metal or similar utensil, concentrates the vast majority of the wear on the bottom surface of the pan. Therefore, to increase the abrasion resistance of the bottom surface of the pan, a wet bonding material layer is applied to the entire cooking surface of the pan followed by a selective application of abrasion resistant particles, such as relatively hard particles, to the bottom surface of the pan. This is accomplished by applying the wet bonding material to all of the surfaces of the pan. Then, a mask or suitable masking material, which does not allow the uniform particles to adhere to or partially adhere to it, is applied to the surfaces of the pan except the bottom surface of the pan. The abrasion resistant particles therefore, will only adhere to the bottom surface of the pan and not to the masked surfaces. In one embodiment, the above applications are followed with a thin application layer of smaller sized dry reinforcing particles to the entire surface of the pan. In all cases, a topcoat including a non-stick material is applied to the entire surface of the pan.

The present embodiment can also be used in industrial applications to reduce cost and/or improve machine tolerances. In one example, the cylindrical area and top of the valve are coated with the wet bonding layer. A uniform dry particle layer is applied by then inverting the solenoid valve so that the uniform dry particles contact the sides of the cylindrical area of the solenoid while it is being rotated. Gravity causes the excess dry particles to drop down providing no dry particles that are adhered to the bottom wet area of the valve of the solenoid. The solenoid surfaces are then completely cured using a suitable curing process. Subsequently, bronze particles are applied to the outside surface of the cylindrical area and then covered with a thin, appropriate topcoat. The face of end surface of the solenoid is only coated with a single coating of the original wet bonding material layer, which has been cured as described above.

Magnetic Particle Embodiment

In a further embodiment, dry magnetic particles are applied to the wet surface of a glass or non-magnetic metal substrate to completely coat the surface of the substrate. In one aspect of this embodiment, a magnetic shape is placed on a surface to be coated, either under, above or both under and above, the surface. The magnetic shape may be any shape, symbol, character or other suitable image. The shape will appear on the surface of the substrate as the magnetic particles orient themselves due to the magnetic forces attracting the magnetic particles while the magnetic particles “float” in the liquid layer. A suitable non-magnetic material, such as aluminum or glass, is used as the substrate.

One example is a glass or metallic baking pan. A wet bonding material is first applied to the surface. Magnetic particles, such as magnetic stainless steel or magnetic iron particles that are dry, are applied to the non-magnetic pan. The wet bonding layer stays moist during this dry magnetic particle application phase. A magnetic image, which might be a company logo, part number, identification or other suitable identifier, is created with a highly magnetic force field. This may be electromagnetic or magnetic in nature comprising a predetermined shape. The magnetic shape can be suspended below and in contact with the pan or it can be suspended slightly above the surface of the magnetic particles, not touching the particles. The magnetic forces will affect the magnetic material that has been introduced as a dry particle to the wet base bonding layer and the shape of the magnetic forces will be shown in the pattern in the coating created by the orientation of the metallic particles.

Various blends of metallic particles can be used and various shapes can be blended into the dry layer so that very distinct images appear in the layer depending on the formulations of the dry particles. In one example, a coffee cup that has had a wet bonding layer applied followed with an application of the dry magnetic material can have a company logo created with an electromagnet or solid magnets, such as Rare Earth or Alnico magnets, which will orient the magnetic particles that have been introduced to the wet bonding layer to create an image that is that of the company's logo. It should be appreciated that the letters would be reversed, in mirror images, if placed below the pan so that the viewing of the pan from the topside, where the wet bonding/dry magnetic particle layer is applied, reads correctly. This could be followed immediately, while the magnetic forces are held in place, with a semi-curing infrared heat cycle which would harden the wet bonding layer so that the orientation of the magnetic particles while they are being magnetized would hold the formed shape. In this embodiment the magnetic particles may be ferrite particles, ferrous particles, or any suitably magnetic materials, including stainless steel. In one aspect of this embodiment, the magnetic particles are densely packed at the surface due to the forces the magnetic field places upon the particles at the surface and on the surface of the substrate. The magnetic contraction or alignment occurs within the wet bonding layer while the magnetic particles “float” before the wet bonding layer is hardened through a curing operation.

In a further embodiment, ferrite particles are applied to the surface or surfaces of a substrate over a wet bonding material layer to absorb microwaves or similar waves such as in a microwave oven. For instance, the ferrite particles may be applied to a wet bonding material layer on a glass container. This step is repeated several times until the ferrite particles, which are chosen for their microwave absorptive capabilities, have sufficient depth to create and transfer energy in the form of heat to food products inside the glass dish while in a microwave oven. In this embodiment, the entire glass dish or bowl would be coated with the wet bonding material layer, which would be opaque in nature. The ferrite particles are introduced only to the bottom of the dish. This would allow, when the complete system is cured, for the microwave energy to be absorbed in the center of the dish. For example, a microwave popcorn maker could be made in such a manner in which the heat was concentrated at the bottom of the microwave vessel, container or dish allowing the newly popped corn to leave the hot surface and be replaced by heavier and denser popcorn as it falls into the center of the curved dish. In another example, medical sterilization equipment could be manufactured with plastic and the bonded ferrite layer, which would produce localized heat in certain areas of the plastic as determined by the introduction of the ferrite particles where necessary.

In a further embodiment, the coated substrate is cured using induction heating. In this embodiment, induction or magnetic sensitive particles such as uniform metal particles are applied to the wet bonding material on the surface of a substrate. The metal particles may include uniform magnetic stainless steel flakes or stainless steel particles. The flakes or particles are rearranged in the wet bonding material using a magnet or other suitable magnetic device. Induction waves, which are reverse magnetic fields, are then directed at the coated substrate to induce heat in the wet bonding material. The heat induced in the wet bonding material cures the wet bonding material to produce the final coated substrate. In another embodiment, an induction heat device is used to raise the temperature of the substrate and thereby cure the wet bonding material layer.

Density of Uniform Particle Layer

In a further embodiment, the strength of the bonds and the layers on the substrate are increased by increasing the density of the uniform dry particles that are applied to the bonding material layer on the surface of a substrate. In one aspect of this embodiment, commercial, unmodified or modified grit blasting or sandblasting equipment is employed to apply the dry particles to the bonding material layer. The density of the particles in the bonding material layer is increased by increasing the pressure of the spray and the velocity of the dry particles and the rate of speed in which the coatings are applied to the bonding material layer. The increased pressure of the dry particle depositing spray and the rate at which the dry coating or dry coatings are applied to the bonding material layer, increases the packing or density of the particles in the wet bonding material layer. The pressure of the spray and/or the rate of speed of the spray may be adjusted to maximize the density of the dry particles based on the desired design specifications.

The high-speed introduction of particles into the bonding material can also be used when multiple-sized dry particles are applied to the surface of a substrate. In one example, a first layer includes relatively small particles of approximately 20-50 microns, followed by the application of relatively large particles of approximately 150 microns followed by the application of relatively small particles of approximately 20-50 microns followed by the application of smaller particles of approximately 10-20 microns. In this embodiment, the density of a 30-40 micron wet bonding material layer is increased and also the interconnectivity or contact between particles is enhanced. This layer, when wet, will be 30 microns, but the finished layer may actually be greater with the 150-micron particles protruding from the surface and causing the surface of the substrate to be slightly textured.

Particle Encapsulation

In an alternative embodiment, the substantially uniform dry particles are pre-treated, encapsulated or micronized with a wet bonding material such as an adhesion promoting encapsulent or catalytic reactive material producing encapsulent prior to being applied to the wet surface on a substrate. One example of an adhesion promoting encapsulant is a silane coupling agent or silane. The wet bonding material applied to the dry particles may be the same or different from the wet bonding material applied to the surface of the substrate as described above. Preferably, the bonding material is compatible with the bonding material layer applied to the surface of the substrate and any other coating layers applied to the substrate. In one embodiment, the particles are placed in a rotary device such as a tumbler. The bonding material is sprayed or applied as droplets into the tumbler and thereby evenly distributes and coats the dry particles as the particles rotate in the tumbler. The bonding material basically coats all of the areas of the dry particles with a thin veneer. The coated particles are dried or semi-cured to encapsulate the dry particles, and then applied to the wet bonding material layer.

In one embodiment, a curing cycle is employed to semi-cure the wet bonding agent or bonding material, which contains a resin and a solvent to the once dry particles. The extra curing process enables the dry particles to adhere to each other and also evaporates or removes the solvent from the base or initial coating layer, which strengthens the bond between the dry particles and a intermediate or lower layer on a surface of a substrate. Thus, pre-coating or pre-treating the dry particles with a bonding material enhances the bonding capabilities of the particles to each other and enhances the bonding strength between the particles and the bonding material layer on the surface of the substrate and subsequent applied layers.

Wave Absorption Embodiment

In one embodiment, the present method is used to attenuate or absorb magnetic, electromagnetic, radio or other airborne waves or signals such as in a medical X-ray room or similar area such as in RF shielding. Currently, sheets of metal such as copper or similar materials are used to cover the surfaces in these areas. In the present method described above, a wet bonding material is applied or sprayed onto a vertical or horizontal surface or substrate such as a wall or floor in a room. In this embodiment, it should be appreciated that the base material layer such as the bonding material layer may have a thickness of approximately 125-150 microns.

After the wet bonding material is applied to the surface or surfaces, a suitable magnetic wave or other suitable absorbing type material such as dry copper particles, which may have a thickness of approximately 50-75 microns, are applied to the wet bonding material layer. These relatively smaller particles fill in the areas that are still wet between the larger particles. Additionally, a leafing material such as silver, nickel, copper, bronze, or any other conductive material may be applied to the uniform dry particles. Once the coated substrate is grounded using the leafing material, the entire exposed surface acts as an electrical conductor such as a sheet of metal. Thus, additional layers can be added to the multiple layers of the original formulation of primer or bonding material. The sequence can be repeated until the thickness of the layers is approximately 400-500 microns or greater. The multiple sized particles in this underlayment contact each other interconnectedly to provide an essentially impermeable barrier to radio waves or any other airborne electromagnetic or electronic waves.

The benefit of the underlayment including the wave reducing or absorbing layer is that the metallic particles are densely compacted into the wet bonding material layer. In conventional coating processes, the particles are applied to the surface of a substrate as a part of the wet coating and therefore, the coating may actually prevent contact between the particles. Conversely, careful formulation of the bonding material layer actually produces a shrinking or cohesive effect which increases the density of the layers as the layers are dried or catalyzed in place.

Thus, the present invention enables the dry copper particles to completely cover the desired surfaces and thereby minimize or eliminate the gaps and seams produced by conventional methods, which cover or line walls in a room with sheet of metal such as copper. Additionally in one embodiment, a flexible bonding material is used to enable the coatings to better adhere to the surfaces, twists and bends of the surfaces such as corners in a room. In one aspect of this embodiment, to enhance the adherence and coverage of the particles to the bonding material layer, an electrically conductive bonding material is used to attract the oppositely charged particles.

In RF shielding on plastic, many materials have been used which contain leafing particles of copper, bronze, and other similar materials to provide a metallic shield over plastic parts. In all cases, these liquid coatings with high-solids metals had problems with distribution of the particles because of the settling characteristics of the heavy metals, particularly the copper and bronze. Also, the uneven distribution of particles caused the particles to remain substantially separated by the carrier resin, which negatively affects the conductivity of the coating. Thus, the coatings must be applied thicker and thicker to minimize or eliminate the voids or separation of the particles in the coating where radio waves or electromagnetic waves may permeate an opening in the coating or coatings.

Adhesives

In one embodiment of the underlayment of the present invention, the materials can be more effectively bonded to the plastics using two-part adhesives, such as epoxy and urethane and a very dense metallic layer, which would include pure metal interconnecting metallurgically with intimate particle-to-particle contact. In this embodiment, the impingement velocity of the dry particles sprayed onto the wet bonding material causes the dry particles to stick to the bonding material layer, which provides a dense particle layer. The density of the particle layer may be increased by using multi-sized and multi-shaped particles. The dry particle layer can be electrically tested before further coatings are applied to the dry particle layer. This enables a user to be able to test the conductivity of the coatings before additional layers are applied and also enables the user to reinforce a section or area of the underlayment with more particles, if more particles are needed based on the conductivity.

INDUSTRIAL APPLICATIONS

In another embodiment, industrial sifters, strainers, filters and similar industrial components, which are comprised of thick plates with perforated holes, are completely coated with wear resistant coating using the underlayment of the present invention. For example, commercial laundry dryers used in hospitals can be six feet or greater in diameter and ten feet or longer, comprising of several curved plates bolted to a structure, which resembles a drum when complete. In this case, the scraping of clothing and plastic items against the non-stick surface or surfaces of the dryers wears the surfaces away. Using the underlayment of the present invention, the non-stick surfaces of the dryers is substantially strengthened and the wear resistance of these surfaces is significantly enhanced.

In another example, a surface or surfaces of industrial centrifuges are coated. Industrial centrifuges incur great wear during operation. With conventional technology, hard particles such as stainless steel particles are made molten and directed towards a surface or surfaces of a substrate such as by using an arc spray or plasma detonation with detonation gun technology, to increase the roughness of the surface or surfaces. This application method, however, typically coats the surface or surfaces which are at right angles to or directly impacted by the spray, but fails to completely coat the inside surfaces of vertical holes which are on surfaces parallel to the direction of the spray.

In the embodiment of the present invention, by using electrostatic spray technology to apply the bonding material layer to the surface or surfaces of the substrate, the uniform dry particles completely cover the flat surface of the inside of the centrifuge, but also, all of the holes that allow media to pass through the centrifuge. By using this electrostatic combination of liquid and subsequent powder-spray application, the inside surface which defines the holes are strengthened through the uniform application of the wear resistant dry particles. Present technology does not strengthen the inside surfaces of the holes. Thus, in conventional centrifuges, the media passing through the holes eventually wears away the soft non-stick coating on the surface or surfaces of the surfaces of the centrifuges. With the present invention, the flat surface and the surface which defines the holes are completely coated and protected. This is substantially different than the conventional technology in that the distribution of the wear-resistant particles in the conventional technology is focused on the flat surfaces and does not completely coat the surfaces. With the present method, the electrostatic attraction of the particles to the wetted surfaces, ensures complete coverage of the bonding material layer to the flat surfaces and the holes.

In a further embodiment, the present invention is employed in a rotary molding system such as a reactor or commercial dryer vessel to improve the wear resistance of the system. The predetermined quantity of bonding material is filled into the vessel such as the reactor cavity or main dryer compartment and rotated in a multi-directional manner to completely and uniformly coat the inside surface of the vessel. Then, suitable substantially uniform abrasive-resistant particles or other suitable particles are filled into the vessel and are applied to the bonding material layer on the inside surface of the vessel using the multi-directional rotation of the vessel described above. After the dry particles coat the surface, the vessel is inverted and the excess particles drop out of the vessel. The bonding material and dry particles on the surface are cured using a suitable curing process and a final coating or topcoat is then applied to the uniform particle layer if desired.

In one example, a powder fluoropolymer topcoat, such as PFA or FEP includes a combination of either a resin with PTFE and/or any suitable and appropriate modifiers and strengthening agents, such as graphite, talc, and lead powder. The underlayment is created and cured at a temperature of approximately 750 degrees Fahrenheit or lower, depending on the bonding resin or material that is used in the process. The fluoropolymer-rich topcoat, which is in powder form, is applied to the underlayment for wear resistance, if necessary, such as in a machine channel or guide or commercial baking pan or similar bakery or food processing equipment.

The underlayment, if it consists of aluminum oxide or similar abrasion-resistant particles, which are very hard, is coated with the fluoropolymer powder mixture and FDA or food contact ingredients are selected to comply with FDA requirements. This allows the creation of a highly wear resistant, non-stick coating with a powder topcoat.

In another example, preparation for arc spraying stainless steel wire and titanium wire, to create a bumpy or rough base requires an extensive amount of grit blasting and surface preparation to roughen the surface for the mechanical grip such that these dissimilar metals, when impinged in a molten state on the surface, cannot bond metallurgically. With the underlayment of the present invention, the dry uniform particles are bonded and tightly adhered to a surface of a substrate through contemporary adhesive technology and function at and beyond the temperature constraints of typical topcoatings, such as PTFE, which has a limit of approximately 550 degrees Fahrenheit. In other words, the adhesive bond strength and temperature capacity of the underlayment is greater than the temperature capacity of the subsequently applied topcoat layers or topcoats.

Multiple Coating Applicators

In an alternative embodiment, a coating system includes a plurality of coating or material applicators, at least one container having a wet bonding material, at least one container having substantially dry particles, wherein the containers are connected to the coating applicators using at least one coating line or tube, which transports the materials from the containers to the coating applicators. It should be appreciated that the coating applicators may be spray guns, electrostatic spray guns, powder spray guns or any other suitable applicators. The coating applicators are positioned adjacent to the surface or surfaces being coated on the substrate.

In one aspect of this embodiment, one of the coating applicators applies the wet bonding material to the surface of the substrate and the other coating applicator applies an even, substantially uniform layer of the dry particles to the wet bonding material layer. The applicators may apply the coatings at the same rate or at different rates. The coating applicators apply each layer to the surface of the substrate until a desired thickness is achieved.

In one example, the coating system includes multiple coating or material applicators such as two electrostatic spray guns or powder spray guns, to apply an epoxy-based material to a surface of a substrate. The epoxy is made up of relatively dry particles which are applied using electrostatic attraction to the surface. While the dry epoxy is in place, a thin layer of a wet bonding material is fog-sprayed or applied to the dry epoxy particles to slightly dampen the surface of the particles. Then, a powder spray of aluminum oxide, bronze, ceramic, glass or any other suitable material is applied to the bonding material on the particles. The layers are then heated or cured. Subsequently, a final coating such as a wet or dry film, may be applied to the cured layers. In one example, an epoxy base is applied to the surface of the substrate. Then, a wet film including a solvent and water is applied to the epoxy to wet the epoxy and provide some stickiness on the surface. A dry powder spray of non-electrostatic particles are then applied to the surface.

It should be appreciated that the underlayment of the present invention can be used as a single process without any topcoats to provide adhesion of paper or grip or tractive strength as related to moving paper or other products with a roller at high speeds. Additionally, the underlayment could be created with approximately 30 to 40 micron thick bonding material layer and an approximately 200-micron sharp particles of aluminum oxide or boron nitride or other very high-wear resistant ceramics and provide an abrasive gripping surface.

It should be understood that various changes and modifications to the presently preferred embodiments described herein will be apparent to those skilled in the art. Such changes and modifications can be made without departing from the spirit and scope of the present invention and without diminishing its intended advantages. It is therefore intended that such changes and modifications be covered by the appended claims. 

The invention is claimed as follows:
 1. A coated substrate comprising: a substrate; a non-stick bonding material secured to a surface of the substrate; a layer of aramid fibers secured to the non-stick bonding material, at least a first portion of a plurality of the aramid fibers each being partially submerged within the non-stick bonding material and at least a second portion of each of said plurality of aramid fibers protruding from the non-stick bonding material; and a top coating secured to the bonding material.
 2. The coated substrate of claim 1, wherein the substrate is selected from the group consisting of: a cooking device, a food processing device, and a food conveyor.
 3. The coated substrate of claim 1, wherein the layer of aramid fibers includes at least two different sized aramid fibers.
 4. The coated substrate of claim 1, wherein the aramid fibers are ground.
 5. A coated substrate comprising: a substrate; a bonding material secured to a surface of the substrate; a single layer of aramid fibers secured to a top of the bonding material; and a top coating secured to the single layer of aramid fibers.
 6. The coated substrate of claim 5, wherein the substrate is selected from the group consisting of: a cooking device, a food processing device, and a food conveyor.
 7. The coated substrate of claim 5, wherein the single layer of aramid fibers includes at least two different sized aramid fibers.
 8. The coated substrate of claim 5, wherein the aramid fibers are ground.
 9. The coated substrate of claim 5, wherein the bonding material is a non-stick bonding material.
 10. A coated substrate comprising: a substrate; a non-stick bonding material secured to a surface of the substrate; and a plurality of aramid fibers in the non-stick bonding material.
 11. The coated substrate of claim 10, wherein the substrate is selected from the group consisting of: a cooking device, a food processing device, and a food conveyor.
 12. The coated substrate of claim 10, wherein the plurality of aramid fibers includes at least two different sized aramid fibers.
 13. The coated substrate of claim 10, wherein the plurality of aramid fibers are ground.
 14. The coated substrate of claim 10, which includes a top coating secured to the bonding material. 